本發明是有關於一種健身設備,且特別是有關於一種具有發電功能的健身設備。The present invention relates to a fitness device, and in particular to a fitness device with a power generation function.
隨著健康及環保意識的提升,同時滿足健身與發電的健身設備應運而生,以供使用者在健身的同時透過健身設備產生電能並儲蓄或直接對電子設備進行充電。詳細而言,整合有發電功能的健身設備大多為有氧健身設備,例如健身車、划船機或橢圓機,以在使用者進行肌耐力訓練及強化心肺功能的同時進行長時間的發電。然而,在未能充分掌握即時生理狀態的情況下,使用者極為容易在短時間內將體能耗盡,不僅無法達到有氧訓練的效益,也難以提高總發電量。With rising awareness of health and environmental protection, fitness equipment that combines fitness and power generation has emerged. This allows users to simultaneously generate and store energy while exercising, or directly charge electronic devices. Specifically, fitness equipment with integrated power generation capabilities is mostly aerobic fitness equipment, such as exercise bikes, rowing machines, or elliptical trainers. These devices generate electricity for extended periods while users train their muscular endurance and strengthen their cardiopulmonary function. However, without adequate understanding of their current physiological state, users can easily exhaust their energy quickly, failing to achieve the benefits of aerobic exercise and increasing overall power generation.
本發明提供一種健身設備,有助於提高使用者的運動效率,同時產生最佳的發電量。The present invention provides a fitness device that helps improve the user's exercise efficiency while generating optimal power generation.
本發明提出一種健身設備,包括傳動裝置、變速箱、發電裝置、蓄電裝置、第一感測器、第二感測器、第三感測器、儲存裝置以及處理器。變速箱耦接於傳動裝置。發電裝置耦接於變速箱。蓄電裝置耦接於發電裝置。第一感測器用於感測傳動裝置的傳動數據。第二感測器用於感測使用者的生理數據。第三感測器用於感測發電裝置的發電數據。處理器耦接於變速箱、第一感測器、第二感測器、第三感測器以及儲存裝置。處理器接收傳動數據、生理數據以及發電數據,並經由人工智慧模型依據傳動數據、生理數據以及發電數據判斷是否調整變速箱的齒輪比。The present invention provides a fitness device comprising a transmission, a gearbox, a power generation device, a power storage device, a first sensor, a second sensor, a third sensor, a storage device, and a processor. The gearbox is coupled to the transmission. The power generation device is coupled to the gearbox. The power storage device is coupled to the power generation device. The first sensor is used to sense transmission data from the transmission. The second sensor is used to sense physiological data of the user. The third sensor is used to sense power generation data from the power generation device. The processor is coupled to the gearbox, the first sensor, the second sensor, the third sensor, and the storage device. The processor receives the transmission data, physiological data, and power generation data, and determines whether to adjust the gear ratio of the gearbox based on the transmission data, physiological data, and power generation data using an artificial intelligence model.
基於上述,本發明的健身設備可依據使用者的生理狀態即時調整變速箱的齒輪比(即調整傳動裝置的阻力),以令使用者能有效率地運動,並拉長總運動時間,以提高發電裝置的總發電量。Based on the above, the fitness equipment of the present invention can adjust the gear ratio of the transmission (i.e., adjust the resistance of the transmission device) in real time according to the user's physiological state, so that the user can exercise efficiently and extend the total exercise time to increase the total power generation of the generator.
為讓本發明的上述特徵和優點能更明顯易懂,下文特舉實施例,並配合所附圖式作詳細說明如下。In order to make the above features and advantages of the present invention more clearly understood, embodiments are given below and described in detail with reference to the accompanying drawings.
圖1是本發明一實施例的健身設備的示意圖。請參考圖1,在本實施例中,健身設備100可為健身車、划船機或橢圓機,且具有發電功能。因此,使用者可透過健身設備100進行長時間的有氧訓練,並透過健身設備100產生較高的總發電量。FIG1 is a schematic diagram of a fitness device according to one embodiment of the present invention. Referring to FIG1 , in this embodiment, fitness device 100 can be an exercise bike, rowing machine, or elliptical trainer, and has a power generation function. Therefore, users can use fitness device 100 for extended aerobic exercise while generating a high total power output.
詳細而言,健身設備100包括處理器110、儲存裝置120、傳動裝置130、變速箱140、發電裝置150、蓄電裝置160、第一感測器101、第二感測器102以及第三感測器103,其中處理器110電性耦接於儲存裝置120、變速箱140、第一感測器101、第二感測器102以及第三感測器103,且發電裝置150電性耦接於蓄電裝置160。另外,傳動裝置130與變速箱140機械性耦接,且變速箱140與發電裝置150機械性耦接。Specifically, fitness equipment 100 includes a processor 110, a storage device 120, a transmission 130, a gearbox 140, a power generator 150, a power storage device 160, a first sensor 101, a second sensor 102, and a third sensor 103. Processor 110 is electrically coupled to storage device 120, gearbox 140, first sensor 101, second sensor 102, and third sensor 103, and power generator 150 is electrically coupled to power storage device 160. Furthermore, transmission 130 is mechanically coupled to gearbox 140, and gearbox 140 is mechanically coupled to power generator 150.
處理器110可以是中央處理器,或是其他可程式化的一般用途或特殊用途的微處理器、數位信號處理器、可程式化控制器、特殊應用積體電路或其他類似元件或上述元件的組合。The processor 110 may be a central processing unit (CPU), or other programmable general-purpose or special-purpose microprocessor, digital signal processor, programmable controller, application-specific integrated circuit (ASIC), or other similar components or a combination of the above components.
儲存裝置120用以儲存資料,且儲存裝置120可包括非揮發性記憶體模組與揮發性記憶體模組。非揮發性記憶體模組可用以非揮發性地儲存資料,例如唯讀記憶體(ROM)、固態硬碟(SSD)及/或傳統硬碟(HDD)。揮發性記憶體模組可用以暫時地儲存資料,例如動態隨機存取記憶體(RAM)。此外,非揮發性記憶體模組及/或揮發性記憶體模組還可以是其他類型的儲存媒體,本發明不加以限制。Storage device 120 is used to store data and may include a non-volatile memory module and a volatile memory module. The non-volatile memory module may be used to store data non-volatilely, such as in read-only memory (ROM), a solid-state drive (SSD), and/or a conventional hard disk drive (HDD). The volatile memory module may be used to temporarily store data, such as in dynamic random access memory (RAM). Furthermore, the non-volatile memory module and/or the volatile memory module may also be other types of storage media, and the present invention is not limited thereto.
在一實施例中,傳動裝置130可為健身車或橢圓機的踏板、曲柄及飛輪,且變速箱140與飛輪機械性耦接。在另一實施例中,傳動裝置130可為划船機的握把、拉繩及風扇,且變速箱140與風扇機械性耦接。此外,傳動裝置130還可以是其他類型的有氧健身設備的傳動機構,本發明不加以限制。In one embodiment, the transmission device 130 may be the pedals, crank, and flywheel of an exercise bike or elliptical machine, with the gearbox 140 mechanically coupled to the flywheel. In another embodiment, the transmission device 130 may be the handle, cable, and fan of a rowing machine, with the gearbox 140 mechanically coupled to the fan. Furthermore, the transmission device 130 may also be a transmission mechanism of other types of aerobic fitness equipment, and the present invention is not limited thereto.
請參考圖1,在本實施例中,第一感測器101可為磁力式轉速感測器或光電式轉速感測器,用於感測傳動裝置130的傳動數據,例如配置於健身車或橢圓機的踏板、曲柄或飛輪,或者是配置於划船機的風扇,以即時反映傳動裝置130的轉速。Please refer to Figure 1. In this embodiment, the first sensor 101 can be a magnetic speed sensor or a photoelectric speed sensor, which is used to sense the transmission data of the transmission device 130, such as the pedals, cranks or flywheels configured on an exercise bike or elliptical machine, or the fan configured on a rowing machine, to reflect the speed of the transmission device 130 in real time.
第二感測器102可用於感測使用者於運動當下的即時生理數據。在一實施例中,第二感測器102可為手握式心率感測器,例如配置於健身車或橢圓機的握把,以即時反映使用者的心率。在另一實施例中,第二感測器102可為胸戴式或腕戴式心率感測器,例如穿戴於使用者的胸口或手腕,以即時反映使用者的心率。在其他實施例中,第二感測器102可為血氧或血壓感測器,以即時反映使用者的血氧濃度或血壓。The second sensor 102 can be used to sense the user's real-time physiological data during exercise. In one embodiment, the second sensor 102 may be a handheld heart rate sensor, such as one mounted on the handlebars of an exercise bike or elliptical trainer, to provide real-time information about the user's heart rate. In another embodiment, the second sensor 102 may be a chest-worn or wrist-worn heart rate sensor, such as one worn on the user's chest or wrist, to provide real-time information about the user's heart rate. In other embodiments, the second sensor 102 may be a blood oxygen or blood pressure sensor to provide real-time information about the user's blood oxygen concentration or blood pressure.
第三感測器103可整合於發電裝置150中的電路,透過偵測發電裝置150中的定子繞組產生的充電電能取得發電數據,例如即時反映發電裝置150的單位時間發電量。The third sensor 103 can be integrated into the circuit of the power generation device 150 to obtain power generation data by detecting the charging energy generated by the stator windings in the power generation device 150, such as reflecting the power generation per unit time of the power generation device 150 in real time.
請參考圖1,在使用者透過健身設備100進行有氧運動的過程中,傳動裝置130與變速箱140可產生機械能,並將機械能傳送至發電裝置150,以透過發電裝置150將機械能轉化為電能,最後,將電能儲蓄於蓄電裝置160,例如鉛酸電池、鋰電池或其他類型的電池。Referring to FIG. 1 , while a user is performing aerobic exercise on fitness equipment 100 , transmission device 130 and gearbox 140 generate mechanical energy and transmit the mechanical energy to generator 150 . Generator 150 converts the mechanical energy into electrical energy, which is then stored in storage device 160 , such as a lead-acid battery, lithium battery, or other type of battery.
隨著使用者的總運動時間拉長,健身設備100產生愈高的總發電量。然而,使用者的生理狀態、傳動裝置130的轉速及變速箱140的齒輪比(例如反映傳動裝置130的阻力)會對發電裝置150的單位時間的發電量、總發電時間及總發電量造成一定程度的影響。As the user's total exercise time increases, the total power generated by the fitness device 100 increases. However, the user's physiological state, the rotational speed of the transmission 130, and the gear ratio of the transmission 140 (e.g., reflecting the resistance of the transmission 130) will have a certain degree of impact on the power generation per unit time, the total power generation time, and the total power generation of the generator 150.
舉例來說,傳動裝置130的轉速越高,發電裝置150的單位時間的發電量也越高,但使用者的生理負荷較大,導致心率拉高而難以維持長時間的運動,造成發電裝置150的總發電時間與總發電量下滑。在使用者維持相同的力量輸出的情況下,若提高變速箱140的齒輪比(即提高傳動裝置130的阻力),則傳動裝置130的轉速可降低,同時讓使用者的心率降低。雖然發電裝置150的單位時間的發電量因傳動裝置130的轉速降低而下滑,但可拉長使用者的總運動時間,以提高發電裝置150的總發電量。For example, a higher speed of the transmission 130 increases the amount of electricity generated per unit time by the generator 150. However, this increases the user's physiological load, leading to an elevated heart rate and difficulty maintaining prolonged exercise. This results in a decrease in the total power generation time and total power generated by the generator 150. While maintaining the same force output, increasing the gear ratio of the transmission 140 (i.e., increasing the resistance of the transmission 130) can reduce the speed of the transmission 130 and, in turn, lower the user's heart rate. Although the power generated per unit time by the generator 150 decreases due to the reduced speed of the transmission 130, the user's total exercise time can be extended, thereby increasing the total power generated by the generator 150.
請參考圖1,在本實施例中,儲存裝置120儲存有人工智慧模型104,其中人工智慧模型104可包括機器學習模型及/或深度學習模型,且用以提高使用者的運動效率、拉長使用者的總運動時間(即拉長發電裝置150的總發電時間)及提高發電裝置150的總發電量。Please refer to Figure 1. In this embodiment, the storage device 120 stores an artificial intelligence model 104, wherein the artificial intelligence model 104 may include a machine learning model and/or a deep learning model, and is used to improve the user's exercise efficiency, extend the user's total exercise time (i.e., extend the total power generation time of the power generation device 150), and increase the total power generation of the power generation device 150.
詳細而言,處理器110接收傳動裝置130的轉速、使用者的心率以及發電裝置150的單位時間的發電量,並經由人工智慧模型104配合發電裝置150的發電效率曲線依據上述至少三個數據判斷是否調整變速箱140的齒輪比。Specifically, the processor 110 receives the rotational speed of the transmission 130, the user's heart rate, and the power generation per unit time of the generator 150, and determines whether to adjust the gear ratio of the transmission 140 based on at least three of the above data through the artificial intelligence model 104 and the power generation efficiency curve of the generator 150.
舉例來說,處理器110可使用訓練資料(至少包含轉速、心率及單位時間的發電量)來配合發電裝置150的發電效率曲線訓練人工智慧模型104,以得到訓練結果。接著,透過處理器110判斷訓練結果是否符合預設結果,並將訓練結果與預設結果的相似度回傳至人工智慧模型104,再使用訓練資料(至少包含轉速、心率及單位時間的發電量)重新訓練人工智慧模型104,直到處理器110判斷訓練結果與預設結果相匹配,則人工智慧模型104完成訓練。For example, processor 110 may use training data (including at least rotational speed, heart rate, and power generation per unit time) to train artificial intelligence model 104 based on the power generation efficiency curve of power generation device 150 to obtain a training result. Processor 110 then determines whether the training result matches the preset result and transmits the similarity between the training result and the preset result back to artificial intelligence model 104. Artificial intelligence model 104 is then retrained using training data (including at least rotational speed, heart rate, and power generation per unit time) until processor 110 determines that the training result matches the preset result, at which point artificial intelligence model 104 completes training.
請參考圖1,處理器110可將傳動裝置130的轉速、使用者的心率以及發電裝置150的單位時間的發電量輸入至人工智慧模型104,並依據人工智慧模型104的輸出判斷是否調整變速箱140的齒輪比。進一步來說,響應於人工智慧模型104的輸出為第一值,處理器110調整變速箱140的齒輪比;而響應於人工智慧模型104的輸出為第二值,不調整變速箱140的齒輪比。Referring to Figure 1 , processor 110 inputs the rotational speed of transmission 130, the user's heart rate, and the power generation per unit time of generator 150 into artificial intelligence model 104. Processor 110 then determines whether to adjust the gear ratio of transmission 140 based on the output of artificial intelligence model 104. Specifically, in response to a first value from the output of artificial intelligence model 104, processor 110 adjusts the gear ratio of transmission 140; in response to a second value from the output of artificial intelligence model 104, processor 110 does not adjust the gear ratio of transmission 140.
在一狀態下,傳動裝置130的轉速過高,且使用者的心率過高(例如逼近無氧心率區間或處於無氧心率區間),導致使用者無法長時間運動同時將發電裝置150維持在較高的單位時間的發電量。經由人工智慧模型104判斷得出應調整變速箱140的齒輪比的結果,處理器110自動依據人工智慧模型104的輸出結果將變速箱140自低齒輪比調整至高齒輪比,以提高傳動裝置130的阻力。在使用者維持相同的力量輸出的情況下,傳動裝置130的轉速可降低,同時讓使用者的心率降低。雖然發電裝置150的單位時間的發電量因傳動裝置130的轉速降低而下滑,但可拉長使用者的總運動時間,以提高發電裝置150的總發電量。也就是說,使用者可省力或有效率地運動,以透過健身設備100產生最佳的發電量。In one situation, the transmission 130's rotational speed is too high, and the user's heart rate is too high (e.g., approaching or within the anaerobic heart rate zone), making it impossible for the user to exercise for a long time while maintaining a high power output per unit time from the generator 150. The artificial intelligence model 104 determines that the gear ratio of the transmission 140 should be adjusted. Based on the output of the artificial intelligence model 104, the processor 110 automatically adjusts the transmission 140 from a low gear ratio to a high gear ratio to increase the resistance of the transmission 130. While the user maintains the same force output, the transmission 130's rotational speed can be reduced, thereby lowering the user's heart rate. Although the power generation per unit time of the power generating device 150 decreases due to the reduced rotation speed of the transmission device 130, the user's total exercise time can be extended to increase the total power generation of the power generating device 150. In other words, the user can exercise with less effort or more efficiency to generate the optimal power through the fitness equipment 100.
在另一狀態下,傳動裝置130的轉速過低,且使用者的心率過低(例如未達有氧心率區間),雖然使用者可長時間運動同時將發電裝置150維持在較低的單位時間的發電量,但未能達到有氧訓練的目標,且總發電量不足。經由人工智慧模型104判斷得出應調整變速箱140的齒輪比的結果,處理器110自動依據人工智慧模型104的輸出結果將變速箱140自高齒輪比調整至低齒輪比,以降低傳動裝置130的阻力。在使用者維持相同的力量輸出的情況下,傳動裝置130的轉速可提高,以提高發電裝置150的單位時間的發電量,同時讓使用者的心率提高,以達到有氧訓練的目標。也就是說,使用者可有效率地運動,以透過健身設備100產生最佳的發電量。In another state, the transmission device 130's speed is too low, and the user's heart rate is too low (e.g., not within the aerobic heart rate zone). Although the user can exercise for a long time while maintaining a relatively low power output per unit time from the generator 150, the aerobic training goal is not achieved, and the total power generation is insufficient. The artificial intelligence model 104 determines that the gear ratio of the transmission 140 should be adjusted. Based on the output of the artificial intelligence model 104, the processor 110 automatically adjusts the transmission 140 from a high gear ratio to a low gear ratio to reduce the resistance of the transmission device 130. While the user maintains the same force output, the rotational speed of the transmission device 130 can be increased to increase the amount of electricity generated per unit time by the generator 150, while also increasing the user's heart rate to achieve the goal of aerobic training. In other words, the user can exercise efficiently to generate optimal electricity through the fitness device 100.
在又一狀態下,傳動裝置130的轉速適中,且使用者的心率維持在有氧心率區間內。因此,使用者可長時間運動同時將發電裝置150維持在適中的單位時間的發電量,不僅能達到有氧訓練的目標,也能提高發電裝置150的總發電量。經由人工智慧模型104判斷得出不調整變速箱140的齒輪比的結果,處理器110自動依據人工智慧模型104的輸出結果維持變速箱140的齒輪比不變。也就是說,使用者可有效率地運動,以透過健身設備100產生最佳的發電量。In another state, the transmission 130 rotates at a moderate speed, and the user's heart rate remains within the aerobic heart rate zone. Therefore, the user can exercise for extended periods while maintaining a moderate power generation rate per unit time from the power generator 150. This not only achieves the goal of aerobic training but also increases the total power generation of the power generator 150. When the artificial intelligence model 104 determines that the gear ratio of the transmission 140 should not be adjusted, the processor 110 automatically maintains the gear ratio of the transmission 140 unchanged based on the output of the artificial intelligence model 104. This allows the user to exercise efficiently, generating optimal power through the fitness device 100.
在一實施例中,在傳動數據、生理數據以及發電數據等感測資料輸入至人工智慧模型104之前,處理器110可先對感測資料執行正規化(normalization)操作。此正規化操作是用以將感測資料的數值正規化(normalize)(例如調整)至特定的數值區間(亦稱為目標數值區間)。舉例來說,目標數值區間可為數值“0”至數值“1”之間,但本案不限於此。舉例來說,當感測資料中的原始數值為“10”時,此正規化操作可用以將此原始數值正規化為“0.1”;而當感測資料中的原始數值為“20”時,此正規化操作可用以將此原始數值正規化為“0.2”等,依此類推。然而,本案不限制要基於何種規則或縮放比例來調整感測資料中的原始數值。In one embodiment, before the sensor data such as transmission data, physiological data, and power generation data are input into the artificial intelligence model 104, the processor 110 may first perform a normalization operation on the sensor data. This normalization operation is used to normalize (e.g., adjust) the values of the sensor data to a specific numerical range (also referred to as a target numerical range). For example, the target numerical range may be between the values "0" and "1", but the present invention is not limited to this. For example, when the original value in the sensor data is "10", this normalization operation can be used to normalize the original value to "0.1"; and when the original value in the sensor data is "20", this normalization operation can be used to normalize the original value to "0.2", and so on. However, this invention does not limit the rules or scaling used to adjust the original values in the sensing data.
換句話說,無論感測資料的原始數值範圍是多少,經過所述正規化操作後,感測資料中的數值皆可以被調整到統一的數值範圍(即目標數值區間)內。在一實施例中,所述正規化操作可用以克服因不同規格、類型或廠牌的感測器所產生的感測資料的規格不一致的情況。在另一實施例中,處理器110也可以不對感測資料進行所述正規化操作,本案不加以限制。In other words, regardless of the original numerical range of the sensor data, after the normalization operation, the values in the sensor data can be adjusted to a uniform numerical range (i.e., the target numerical range). In one embodiment, the normalization operation can be used to overcome the inconsistency of sensor data generated by sensors of different specifications, types, or brands. In another embodiment, the processor 110 may not perform the normalization operation on the sensor data, which is not limited in this case.
圖2是本發明另一實施例的健身設備的示意圖。請參考圖2,本實施例的健身設備100A與前一實施例的健身設備100的差異在於:健身設備100A更包括觸控顯示裝置170。詳細而言,觸控顯示裝置170耦接於處理器110,且用以顯示傳動數據、生理數據以及發電數據。因此,使用者可透過觸控顯示裝置170即時得知當前的傳動數據、生理數據以及發電數據。Figure 2 is a schematic diagram of another embodiment of a fitness device according to the present invention. Referring to Figure 2 , fitness device 100A of this embodiment differs from fitness device 100 of the previous embodiment in that fitness device 100A further includes a touchscreen display 170. Specifically, touchscreen display 170 is coupled to processor 110 and is used to display transmission data, physiological data, and power generation data. Therefore, users can view current transmission data, physiological data, and power generation data in real time via touchscreen display 170.
另一方面,當處理器110依據人工智慧模型104的輸出判斷為建議調整變速箱140的齒輪比時,處理器110經由觸控顯示裝置170顯示操作指令,並根據使用者所選擇的操作指令判斷是否調整變速箱140的齒輪比。舉例來說,操作指令可為調高整變速箱140的齒輪比與不調整變速箱140的齒輪比等二個選項或調低整變速箱140的齒輪比與不調整變速箱140的齒輪比等二個選項,而使用者可觸碰任一選項來決定變速箱140的齒輪比。On the other hand, when the processor 110 determines that adjusting the gear ratio of the transmission 140 is recommended based on the output of the artificial intelligence model 104, the processor 110 displays an operation instruction via the touch display device 170 and determines whether to adjust the gear ratio of the transmission 140 based on the operation instruction selected by the user. For example, the operation instruction may include two options: increasing the gear ratio of the transmission 140 or not adjusting the gear ratio of the transmission 140, or decreasing the gear ratio of the transmission 140 or not adjusting the gear ratio of the transmission 140. The user can touch either option to determine the gear ratio of the transmission 140.
也就是說,經由人工智慧模型104判斷得出應調整變速箱140的齒輪比的結果時,處理器110並未直接依據人工智慧模型104的輸出結果調整變速箱140的齒輪比,而是提供使用者操作建議,以由使用者自行決定後續的運動與發電模式。That is, when the artificial intelligence model 104 determines that the gear ratio of the transmission 140 should be adjusted, the processor 110 does not directly adjust the gear ratio of the transmission 140 based on the output of the artificial intelligence model 104, but instead provides the user with operational recommendations so that the user can decide the subsequent movement and power generation mode.
綜上所述,本發明的健身設備可依據使用者的生理狀態即時調整變速箱的齒輪比(即調整傳動裝置的阻力),以令使用者能保持在有氧心率區間進行有效率地運動,並拉長總運動時間,以提高發電裝置的總發電量。In summary, the fitness equipment of the present invention can adjust the gear ratio of the transmission (i.e., adjust the resistance of the transmission device) in real time according to the user's physiological state, so that the user can maintain an aerobic heart rate zone for efficient exercise and extend the total exercise time to increase the total power generation of the generator.
雖然本發明已以實施例揭露如上,然其並非用以限定本發明,任何所屬技術領域中具有通常知識者,在不脫離本發明的精神和範圍內,當可作些許的更動與潤飾,故本發明的保護範圍當視後附的申請專利範圍所界定者為準。Although the present invention has been disclosed above by way of embodiments, they are not intended to limit the present invention. Any person having ordinary skill in the art may make slight modifications and improvements without departing from the spirit and scope of the present invention. Therefore, the scope of protection of the present invention shall be determined by the scope of the attached patent application.
100、100A:健身設備 101:第一感測器 102:第二感測器 103:第三感測器 104:人工智慧模型 110:處理器 120:儲存裝置 130:傳動裝置 140:變速箱 150:發電裝置 160:蓄電裝置 170:觸控顯示裝置100, 100A: Fitness equipment101: First sensor102: Second sensor103: Third sensor104: Artificial intelligence model110: Processor120: Storage device130: Transmission device140: Gearbox150: Power generation device160: Power storage device170: Touchscreen display device
圖1是本發明一實施例的健身設備的示意圖。 圖2是本發明另一實施例的健身設備的示意圖。Figure 1 is a schematic diagram of a fitness device according to one embodiment of the present invention.Figure 2 is a schematic diagram of a fitness device according to another embodiment of the present invention.
100:健身設備100: Fitness Equipment
101:第一感測器101: First Sensor
102:第二感測器102: Second sensor
103:第三感測器103: Third Sensor
104:人工智慧模型104: Artificial Intelligence Model
110:處理器110: Processor
120:儲存裝置120: Storage device
130:傳動裝置130: Transmission device
140:變速箱140: Gearbox
150:發電裝置150: Power Generation Device
160:蓄電裝置160: Power storage device
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW111146901ATWI890971B (en) | 2022-12-07 | 2022-12-07 | Fitness equipment with power generation function |
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW111146901ATWI890971B (en) | 2022-12-07 | 2022-12-07 | Fitness equipment with power generation function |
| Publication Number | Publication Date |
|---|---|
| TW202425491A TW202425491A (en) | 2024-06-16 |
| TWI890971Btrue TWI890971B (en) | 2025-07-21 |
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| TW111146901ATWI890971B (en) | 2022-12-07 | 2022-12-07 | Fitness equipment with power generation function |
| Country | Link |
|---|---|
| TW (1) | TWI890971B (en) |
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