TWI520064B - Massage bathing maintain system and maintain method of the same - Google Patents

Description

Massage bath maintenance system and method thereof

The present invention relates to a massage bath maintenance system and method thereof, particularly in the field of massage bathing equipment such as jacuzzi or jacuzzi or swimming pool.

In the prior art, when the massage bath device or its related peripheral device fails, the technician cannot prepare the relevant spare parts in advance before the on-site inspection by the technician, which may result in prolonged maintenance time. Of course, the technician can prepare all the relevant spare parts, but this is not economical. Therefore, it is an urgent problem to solve the problem before the technician arrives at the scene so that he can prepare the spare parts that may be needed.

Therefore, it is necessary to propose a massage bath maintenance system and method thereof to solve the above problems.

In order to solve the above problems, one of the main objects of the present invention is to provide a massage bath maintenance system suitable for massage bathing equipment, and for quickly knowing the operating state of the overall system and for prompt and proper maintenance, including at least one An additional device, at least one slave device, a master device, and an analysis unit. The at least one additional device is adapted to act on the massage bathing device. The at least one slave device is provided with a control unit for generating and transmitting at least one actuation message according to at least one actuation state of the at least one accessory device. The master device is used for The master-slave connection controls the at least one slave device to receive the at least one action message, and the master device includes a work log collecting unit, configured to record the at least one action message transmitted by the at least one slave device A work log in the table. The analyzing unit is configured to analyze the at least one action message in the work log table to determine whether the action of the at least one additional device has an abnormal state.

In an embodiment, the at least one slave device is a massage bath control unit and/or the analysis unit is disposed in the master device.

In an embodiment, the at least one additional device is disposed in the at least one slave device.

In an embodiment, the main control device further includes a memory unit for storing the work log table, wherein the work log table is further configured to store a communication record between the master device and the at least one slave device.

In an embodiment, the analyzing unit queries a built-in table according to the at least one action message to determine whether there is an abnormal state and/or an aging state.

In one embodiment, the actuation message is an anomaly code or a physical value or a chemical value.

In an embodiment, the physical value is a voltage value or a current value.

In an embodiment, the control unit of the at least one slave device generates and transmits the at least one actuation message to the master device or other slave device according to at least one predetermined self-detection operation procedure.

In an embodiment, the master device generates at least one control message to the at least one slave device to command the control unit of the at least one slave device to generate and transmit the at least one actuation message.

In an embodiment, the master device generates a notification message according to the determination result of the at least one action message.

In an embodiment, the massage bath maintenance system further includes an operation panel unit electrically connected to the main control device and having a display screen for displaying the notification message.

In an embodiment, the massage bath maintenance system further includes at least one wireless communication transceiver connected to the master device and the at least one slave device to perform remote debug maintenance.

In an embodiment, the massage bath maintenance system further includes a wireless communication transceiver and a cloud server, the cloud server includes at least one cloud database, an authentication management component, a device management component, an instant messaging management component, and a remote End detection maintenance management component, the remote detection maintenance management component includes the analysis unit, the at least one cloud database is configured to store a corresponding serial number of the massage bath device, and the at least one wireless communication transceiver is connected to the cloud server And sending the work log table to the at least one cloud database of the cloud server for storage by using the master device.

In an embodiment, the cloud server issues a command to the master device to collect the at least one action message from the at least one slave device and record the work log table, and store the work log table in the master control device. And storing the at least one cloud database of the cloud server in the device and/or via the master device for storage.

In an embodiment, the cloud server causes the remote detection maintenance management component to perform at least one predetermined remote detection maintenance management according to the determination result of the at least one actuation message in the work log table by the analysis unit. program.

In an embodiment, the master device is configured according to the at least one predetermined remote detection dimension The management program generates the at least one control message to the at least one slave device to command the control unit of the at least one slave device to perform warm boot and detection, and the at least one slave device generates the at least the detection result An action message.

In an embodiment, the master device performs at least one maintenance operation on the at least one slave device according to the at least one predetermined remote detection maintenance management program, and after executing the at least one maintenance operation, commands the at least one The control unit of the slave device performs the detection, and the at least one slave device generates the at least one actuation message including the detection result, wherein the at least one maintenance operation includes an error setting correction, a cold boot, a source code refill, and a program version. A combined operation of at least one or more of the updates.

In order to solve the above problems, one of the objects of the present invention is to provide a massage bath maintenance system suitable for a massage bath apparatus comprising at least one additional device, at least one slave device, a master device and an analysis unit.

The at least one additional device is adapted to act on the massage bathing device. The at least one slave device is provided with a detection feedback device and a control unit, and the control unit is configured to generate and transmit at least one actuation message according to at least one actuation state of the at least one additional device. The master device controls the at least one slave device by a master-slave connection, and the master device includes a work log collecting unit to record the at least one action message in a work log table. The analyzing unit is configured to analyze the at least one action message in the work log table to determine whether the at least one additional device has an abnormal state. The control unit controls the detection feedback device to detect the at least one additional device and generate the at least one actuation message including the detection result for transmission to the main control device.

In an embodiment, the at least one slave device is a massage bath control unit.

In an embodiment, the at least one additional device comprises a blower, a motor, and an air pump One or a combination of valves, sensors, pumps, ozone generators, lighting controls, and heaters.

In an embodiment, the master device requests the at least one slave device to return the at least one actuation message.

In an embodiment, the at least one additional device is disposed in the at least one slave device.

In an embodiment, the massage bath maintenance system further includes a wireless communication transceiver and a cloud server, the cloud server includes at least one cloud database, an authentication management component, a device management component, an instant messaging management component, and a remote End detection maintenance management component, the remote detection maintenance management component includes the analysis unit, the at least one cloud database is configured to store a corresponding serial number of the massage bath device, and the at least one wireless communication transceiver is connected to the cloud server And then transferring the work log table from the master device to the cloud database of the cloud server for storage.

In an embodiment, the remote detection maintenance management component of the cloud server issues a command to the main control device to request the at least one slave device to return the at least one actuation message.

In an embodiment, the cloud server causes the remote detection maintenance management component to perform at least one predetermined remote detection maintenance management according to the determination result of the at least one actuation message in the work log table by the analysis unit. program.

In an embodiment, the master device generates the at least one control message to the at least one slave device according to the at least one predetermined remote detection maintenance management program, to command the control unit of the at least one slave device to execute Warming up and detecting, and the at least one slave device generates the at least one actuation message including the detection result.

In an embodiment, the master device performs at least one maintenance operation on the at least one slave device according to the at least one predetermined remote detection maintenance management program, and after executing the at least one maintenance operation, commands the at least one The control unit of the slave device performs the detection, and the at least one slave device generates the at least one actuation message including the detection result, wherein the at least one maintenance operation includes an error setting correction, a cold boot, a source code refill, and a program version. A combination of at least one or more of the updates.

In an embodiment, the main control device performs the at least one of the maintenance operations on the control unit via a maintenance interface.

In an embodiment, the service interface can be one or both of JTAG or RESET.

In one embodiment, the detection feedback device includes at least one switch unit and at least one sensing unit, and the at least one switch unit is controlled by the control unit to turn on or off a power supply for the at least one additional device, the at least a sensing unit is configured to detect a specific physical value between the at least one switching unit and the at least one additional device, and transmit the measured specific physical value to the control unit, according to the measured specific physical value by the control unit And generating, by the foregoing detection result, the at least one actuation message and providing the at least one actuation message to the main control device.

In one embodiment, the detection feedback device includes at least one switch unit and at least one sensing unit, and the at least one switch unit is controlled by the control unit to turn on or off a power supply for the at least one additional device, the at least a sensing unit is configured to detect a specific physical value of the at least one additional device, and transmit the measured specific physical value to the control unit, and the control unit uses the measured specific physical value as the detection result to generate the at least And actuating the message and providing the at least one action message to the master device.

In one embodiment, the detection feedback device includes at least one switch unit and at least one sensing unit, and the at least one switch unit is controlled by the control unit to turn on or off a power supply for the at least one additional device, the at least a sensing unit is configured to detect a specific physical value between the power supply of the at least one additional device and the at least one additional device, and transmit the measured specific physical value to the control unit, and the control unit is configured according to the The specific physical value is used as the detection result to generate the at least one actuation message and to provide the at least one actuation message to the main control device.

In an embodiment, the at least one switching unit is a relay, and the physical value is a current value or a voltage determination logic value.

In an embodiment, the detection and feedback device further includes a temperature measurement deviation confirmation device electrically connected to the control unit, configured to detect a temperature state of a thermometer to make the detection result, and the control unit is configured according to the detection result. Generating and transmitting the at least one actuation state to the master device.

In one embodiment, the temperature measurement deviation confirmation device has a temperature sensor and a voltage verification unit, and the temperature sensor and the data measured by the voltage verification unit are used to determine whether the temperature sensor is abnormal.

In an embodiment, the analyzing unit queries a built-in table according to the at least one action message to determine whether there is an abnormal state and/or an aging state.

In order to solve the above problems, one of the objects of the present invention is to provide a massage bath maintenance method, the method comprising the steps of: firstly, at least one slave device generates at least one actuation message according to at least one additional device corresponding to the action of the massage bath device and Storing the at least one actuation message in a master device The built-in at least one work log table, wherein the master device is connected to the at least one slave device by a master-slave. Then, the at least one action message of the at least one additional device is queried through the work log table stored by the master device. Then, the at least one action message of the at least one additional device in the work log table is analyzed by an analyzing unit to confirm whether the at least one additional device has an abnormality or an aging state to issue a notification message. Next, it is confirmed by the master device whether or not the abnormal state has been excluded.

In an embodiment, first, the serial number of the massage bath device is obtained from at least one cloud database of a cloud server. Then, the cloud server confirms that the serial number is valid. Then, the network connection between the cloud server and the main control device is established by using at least one wireless communication transceiver.

In an embodiment, first, a master-slave connection between the at least one slave device and the master device is established.

In an embodiment, when the cloud server confirms that the serial number is invalid or the network connection between the cloud server and the master device cannot be established, then the notification message is sent by the cloud server. The personnel were on site for repairs. Finally, the method ends.

In an embodiment, when the network between the cloud server and the main control device is connected, the cloud server queries the at least one operation of the at least one additional device in the work log table by the main control device. message. And determining, by the analyzing unit located in the cloud server, whether the at least one additional device has an abnormal state according to the at least one action message, wherein the cloud server is at least one when it is confirmed that the at least one additional device is in an abnormal state. The slave device performs a predetermined remote detection maintenance management program.

In an embodiment, first, determining whether the at least one slave device is set incorrectly An error, wherein when it is determined that the at least one slave device is set incorrectly, the setting of the at least one slave device is corrected according to a setting of the cloud server. Then, a corrected and set action message is generated and returned to the cloud server. Next, it is confirmed whether the at least one slave device is operating normally. Next, confirm that there are no other faults. Finally, the method ends.

In an embodiment, when the at least one slave device is not in normal operation, the method further includes the following steps: First, the notification message is sent by the cloud server to notify the person to perform the repair. Finally, the method ends.

In an embodiment, when it is determined that the at least one slave device is operating normally or when other faults are confirmed, the method further includes the following steps: First, it is confirmed whether there is an abnormality in the peripheral communication. Then, the at least one slave device is controlled to perform a warm-on reset. Then, the at least one actuation message is generated. Next, it is confirmed whether the at least one slave device is operating normally. Next, confirm that there are no other faults.

In an embodiment, when it is confirmed that the at least one slave device is not working normally, the method further includes the following steps: First, controlling the at least one slave device to perform a cold boot reset. Then, the at least one actuation message is generated. Next, it is confirmed that the at least one slave device is operating normally. Next, confirm that there are no other faults.

In an embodiment, when it is confirmed that there is another fault or the peripheral communication is normal, the method further includes the following steps: First, reinstalling to the at least one slave device with the existing program version. Next, it is confirmed whether the at least one slave device is operating normally.

In an embodiment, when the at least one slave device is not operating normally, the method further comprises the steps of: first, confirming whether the program version of the at least one slave device is too old. Then, if yes, the program version of the at least one slave device is updated. Then, the at least one actuation message is generated and recorded in the work log table. Next, it is confirmed whether the at least one slave device is operating normally.

In an embodiment, when it is confirmed that the program version of the at least one slave device is new or the at least one slave device is not working normally, the method further includes the following steps: first, the notification message is sent by the cloud server to notify the person On-site maintenance. Finally, the method ends.

In order to solve the above problems, one of the main objects of the present invention is to provide a self-detection method for a massage bath maintenance system, the massage bath maintenance system including an operation panel unit, a main control device, at least one additional device, an analysis unit, and a Massage bath control unit. The operation panel unit is electrically connected to the main control device and has a display screen for displaying a state in which the at least one additional device is actuated to a massage bath device. The main control device is electrically connected to the massage bath control unit and includes a work log collecting unit. The massage bath control unit is electrically connected to the at least one additional device and includes a detection feedback device and a control unit. The detection feedback device is configured to detect the at least one additional device. The control unit is configured to control the detection feedback device and generate and transmit at least one actuation message to the main control device according to the detection result, so that the work log collecting unit of the main control device records the at least one actuation message in the In the work log table. The analyzing unit analyzes the at least one actuation message to determine whether the at least one additional device is malfunctioning and/or aging occurs. Each of the at least one detection feedback device includes at least one switching unit and at least one sensing unit. The at least one switch unit includes a first switch unit, a second switch unit, and a third switch unit. The method includes: first, the control unit performs at least one continuity test procedure of the at least one switching unit. Then, the control unit performs at least one aging and fault testing process of the at least one additional device. Then, the control unit performs at least one non-conduction test flow of the at least one switch unit. Finally, the method ends.

In an embodiment, the at least one continuity test procedure of the at least one switching unit further comprises: first, not turning on the first switching unit, the second switching unit, and the third switching unit. Then, the first switching unit, the second switching unit, and the third switching unit are turned on sequentially or not. Next, it is confirmed whether at least one of the first switching unit, the second switching unit, and the third switching unit can be normally turned on. Then, it is recorded in the work log table and/or displayed on the display screen.

In an embodiment, the at least one aging and fault testing process of the at least one additional device comprises: first, the analyzing unit calculates an aging slope of current and time of the at least one additional device according to the working log table. Then, the analyzing unit determines whether the at least one additional device needs to be replaced according to the aging slope. Next, the analysis unit confirms whether the current of the at least one additional device is less than a predetermined current.

In an embodiment, the at least one non-conduction test procedure of the at least one switch unit includes: first, turning on the first switch unit, the second switch unit, and the third switch unit. Then, the first switch unit and the second switch unit are not turned on sequentially or sequentially. And the third switching unit. Next, it is confirmed whether at least one of the first switching unit, the second switching unit, and the third switching unit is normally non-conductive. Then, it is recorded in the work log table and/or displayed on the display screen.

In an embodiment, when it is confirmed that the combination of one or more of the first switch unit, the second switch unit, and the third switch unit is not normally non-conductive, the method further includes the following steps: first, generating the at least one The actuation message is recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when the analyzing unit determines that the at least one additional device needs to be replaced according to the aging slope, the method further includes the following steps: first, generating the at least one actuation message to be recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when the analyzing unit confirms that the current of the at least one additional device is greater than or equal to the predetermined current, the method further includes the following steps: first, generating the at least one actuation message to be recorded in the work log table and/or displayed on the The display screen. Finally, the method ends.

In an embodiment, when it is confirmed that the combination of one or more of the first switch unit, the second switch unit, and the third switch unit is not normally turned on, the method further includes the following steps: first, generating the at least one action The message is recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, the at least one additional device comprises a heater.

In an embodiment, the at least one switching unit is a relay, and the at least one sensing unit is a current sensing unit and/or a photocoupler.

In order to solve the above problems, one of the objects of the present invention is to provide a self-detection method for a massage bath maintenance system including an operation panel unit, a main control device, at least one additional device, an analysis unit, and a massage. Bath control unit. The operation panel unit is electrically connected to the main control device and has a display screen for displaying a state in which the at least one additional device is actuated to a massage bath device. The main control device is electrically connected to the massage bath control unit and includes a work log collecting unit. The massage bath control unit is electrically connected to the at least one additional device and includes a detection feedback device and a control unit. The detection feedback device is configured to detect the at least one additional device. The control unit is configured to control the detection feedback device and generate and transmit at least one actuation message to the main control device according to the detection result, so that the work log collecting unit of the main control device records the at least one actuation message in the In the work log table. The analyzing unit analyzes the at least one actuation message to determine whether the at least one additional device is malfunctioning and/or aging occurs. Each of the at least one detection feedback device includes at least one switching unit and at least one sensing unit. The at least one switching unit includes a first switching unit and a second switching unit. The self-detection method includes: first, the control unit performs at least one continuity test procedure of the at least one switch unit. Then, the control unit performs at least one aging and fault testing process of the at least one additional device. Then, the control unit performs at least one non-conduction test flow of the at least one switch unit. Finally, the method ends.

In an embodiment, the at least one continuity test procedure of the at least one switch unit further includes: First, the first switching unit and the second switching unit are not turned on. Then, the first switching unit and the second switching unit are turned on sequentially or not. Then, it is confirmed whether at least one of the first switching unit and the second switching unit can be normally turned on. Then, it is recorded in the work log table and/or displayed on the display screen.

In an embodiment, the at least one aging and fault testing process of the at least one additional device comprises: first, the analyzing unit calculates an aging slope of current and time of the at least one additional device according to the working log table. Then, the analyzing unit determines whether the at least one additional device needs to be replaced according to the aging slope. Next, the analysis unit confirms whether the current of the at least one additional device is less than a predetermined current.

In an embodiment, the at least one non-conduction test procedure of the at least one switch unit includes: first, turning on the first switch unit and the second switch unit. Then, the first switching unit and the second switching unit are not turned on sequentially or sequentially. Then, it is confirmed whether at least one of the first switching unit and the second switching unit can be normally non-conductive. Then, it is recorded in the work log table and/or displayed on the display screen.

In an embodiment, when it is confirmed that the combination of one or more of the first switching unit and the second switching unit is not normally non-conductive, the method further includes the following steps: first, generating the at least one actuation message to record in the work The log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when the analyzing unit determines that the at least one additional device needs to be replaced according to the aging slope, the method further includes the following steps: First, generating the at least one actuation message is recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when the analyzing unit confirms that the current of the at least one additional device is greater than or equal to the predetermined current, the method further includes the following steps: first, generating the at least one actuation message to be recorded in the work log table and/or displayed on the The display screen. Finally, the method ends.

In an embodiment, when the current of the at least one additional device has a combination of one or more of a high frequency change, an instantaneous pulse, and a low frequency change, the method further includes the following steps: first, generating the at least one actuation message Recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when it is confirmed that one or both of the first switch unit and the second switch unit are not normally turned on, the method further includes the following steps: first, generating the at least one action message to be recorded in the work log table and / or displayed on the display. Finally, the method ends.

In one embodiment, the at least one additional device comprises one or a combination of a blower, a motor, an air pump, an inductor, a pump, a heater, an ozone generator, and a light control device.

In an embodiment, the at least one switching unit is a relay, and the at least one sensing unit is a current sensing unit and/or a photocoupler.

In order to solve the above problems, an object of the present invention is to provide a self-detection method for a massage bath maintenance system, the massage bath maintenance system including an operation panel unit, a main control device, at least one additional device, an analysis unit, and a massage bath control unit. The operation panel unit is electrically connected to the main control device and has a display screen for displaying a state in which the at least one additional device is actuated to a massage bath device. The main control device is electrically connected to the massage bath control unit and includes a work log collecting unit. The massage bath control unit is electrically connected to the at least one additional device and includes a detection feedback device and a control unit. The detection feedback device is configured to detect the at least one additional device. The control unit is configured to control the detection feedback device and generate and transmit at least one actuation message to the main control device according to the detection result, so that the work log collecting unit of the main control device records the at least one actuation message in the In the work log table. The analyzing unit analyzes the at least one actuation message to determine whether the at least one additional device is malfunctioning and/or aging occurs. Each of the at least one detection feedback device includes at least one switching unit and at least one sensing unit. The self-detection method includes: first, the control unit performs at least one continuity test procedure of the at least one switch unit. Then, the control unit performs at least one aging and fault testing process of the at least one additional device. Then, the control unit performs at least one non-conduction test flow of the at least one switch unit. Finally, the method ends.

In an embodiment, the at least one continuity test procedure of the at least one switching unit further comprises: first, not turning on the at least one switching unit. Then, the at least one switching unit is turned on. Next, it is confirmed whether the at least one switching unit can be normally turned on. Then, it is recorded in the work log table and/or displayed on the display screen.

In an embodiment, the at least one aging and fault testing process of the at least one additional device comprises: first, the analyzing unit calculates the at least one additional device according to the working log table An aging slope of current versus time. Then, the analyzing unit determines whether the at least one additional device needs to be replaced according to the aging slope. Next, the analysis unit confirms whether the current of the at least one additional device is less than a predetermined current.

In an embodiment, the at least one non-conduction test procedure of the at least one switch unit includes: first, turning on the at least one switch unit. Then, the at least one switching unit is not turned on. Next, it is confirmed whether the at least one switching unit can be normally not turned on. Then, it is recorded in the work log table and/or displayed on the display screen.

In an embodiment, when it is confirmed that the at least one switch unit is not normally non-conductive, the method further includes the following steps: First, generating the at least one action message is recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when the analyzing unit determines that the at least one additional device needs to be replaced according to the aging slope, the method further includes the following steps: first, generating the at least one actuation message to be recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when the analyzing unit confirms that the current of the at least one additional device is greater than or equal to the predetermined current, the method further includes the following steps: first, generating the at least one actuation message to be recorded in the work log table and/or displayed on the The display screen. Finally, the method ends.

In an embodiment, when the current of the at least one additional device has a combination of one or more of a high frequency change, an instantaneous pulse, and a low frequency change, the method further includes the following steps: First, generating the at least one actuation message is recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In an embodiment, when it is confirmed that the at least one switch unit is not normally turned on, the method further includes the following steps: First, generating the at least one action message is recorded in the work log table and/or displayed on the display screen. Finally, the method ends.

In one embodiment, the at least one additional device comprises one or a combination of a blower, a motor, an air pump, an inductor, a pump, a heater, an ozone generator, and a light control device.

In an embodiment, the at least one switching unit is a relay, and the at least one sensing unit is a current sensing unit and/or a photocoupler.

100, 200, 300, 400, 500‧‧‧ massage bath maintenance system

1000‧‧‧Master control unit

1010‧‧‧ memory unit

1011‧‧‧Work log table

1020‧‧‧Work log aggregation unit

1100‧‧‧Operation panel unit

1110‧‧‧ display screen

1200‧‧‧Wireless communication transceiver

1300‧‧‧Maintenance interface

1400‧‧‧ power supply

1700‧‧‧ slave control device

2000‧‧‧Massage bath control unit

2010‧‧‧First switch unit

2020‧‧‧Second switch unit

2030‧‧‧3rd switch unit

2100‧‧‧Control unit

2200‧‧‧Detection feedback device

2210‧‧‧ Temperature measurement deviation confirmation device

2211‧‧‧ Temperature sensor

2212‧‧‧Voltage detection unit

2220‧‧‧Sensor unit, optocoupler

2300‧‧‧Second slave device

2310‧‧‧External lighting control unit

2320‧‧‧Internet devices

2330‧‧‧Video playback device

2340‧‧‧Voice and music installation

2350‧‧‧External storage device

2400‧‧‧First slave device

3000‧‧‧Additional devices

3100‧‧‧First add-on

3110‧‧‧Divisional water spray device

3120‧‧‧Automatic water supply device

3130‧‧‧Photographing device

3140‧‧‧Infrared device

3150‧‧‧ Ultrasonic device

3160, 3250‧‧‧

3170, 3230‧‧‧ heater

3200‧‧‧Second attachment

3210‧‧‧Light control device

3220‧‧‧hair dryer

3240‧‧‧Air valve

3260‧‧‧ sensor

3270‧‧Ozone generator

3280‧‧ ‧Motor

4000‧‧‧Massage bath equipment

5000‧‧‧Cloud Server

5100‧‧‧Cloud database

5200‧‧‧Certification Management Components

5300‧‧‧Device Management Components

5400‧‧‧ Instant messaging management component

5410‧‧‧Message incoming management and queue management

5500‧‧‧Remote detection maintenance management component

5510‧‧‧Analysis unit

7000‧‧‧Remote Detection Maintenance Manager

S01-S27, S101-S109, S201-S204, S301-S314, S401-S413, S501-S518, S601-S618, S30301-S30354, S31001-S31054‧‧

1 is a schematic view of a massage bath maintenance system in accordance with a first preferred embodiment of the present invention.

2 is a schematic view showing a massage bath maintenance system according to a second preferred embodiment of the present invention.

FIG. 3 is a schematic diagram showing the composition of the main control device in FIG. 2.

FIG. 4 is a schematic diagram showing the composition of the cloud server in FIG. 2.

Fig. 5 is a view showing the composition of the operation panel unit in Figs. 1 and 2.

Figure 6 is a schematic view showing the composition of the additional device in Figures 1 and 2.

FIG. 7 is a schematic diagram showing the composition of the second slave device in FIG. 2.

Figure 8 is a schematic view showing a massage bath maintenance system in accordance with a third preferred embodiment of the present invention.

Figure 9 is a schematic view showing a massage bath maintenance system in accordance with a fourth preferred embodiment of the present invention.

Fig. 10 is a schematic view showing the first composition state of the massage bath control unit and the second attachment means of the massage bath maintenance system of Fig. 9.

Fig. 11 is a view showing the composition of the temperature measurement deviation confirming device in Fig. 10.

Fig. 12 is a schematic view showing the second composition state of the massage bath control unit and the second attachment means of the massage bath maintenance system of Fig. 9.

Fig. 13 is a schematic view showing a third composition state of the massage bath control unit and each of the second attachment devices of the massage bath maintenance system of Fig. 9.

Figure 14 is a schematic view showing a massage bath maintenance system in accordance with a fifth preferred embodiment of the present invention.

Fig. 15 is a schematic view showing the composition of a plurality of first slave devices of the main control device of the massage bath maintenance system of Fig. 14.

Figure 16 is a diagram showing a first control timing chart of the massage bath maintenance system of the present invention.

Figure 17 is a timing chart showing the second control of the massage bath maintenance system of the present invention.

Figure 18 is a flow chart showing the massage bath maintenance method of the massage bath maintenance system of the present invention.

Figure 19 is a flow chart showing the detection method of the massage bath maintenance system of the present invention.

Figure 20 is a schematic view showing the first composition of the massage bath control unit of the massage bath maintenance system of the present invention.

Figure 21 is a schematic view showing the second composition of the massage bath control unit of the massage bath maintenance system of the present invention.

Figure 22 is a schematic flow chart showing a self-detecting method of a massage bath maintenance system in accordance with a preferred embodiment of the present invention.

Fig. 23 is a detailed flow chart showing the use of three switching units in step S201 in Fig. 22.

Fig. 24 is a detailed flow chart showing the use of three switch units in step S203 in Fig. 22.

Fig. 25 is a detailed flow chart showing the use of the two switching units in step S201 in Fig. 22.

Fig. 26 is a detailed flow chart showing the use of the two switching units in step S203 in Fig. 22.

Fig. 27 is a detailed flow chart showing the use of a switch unit in step S201 in Fig. 22.

Fig. 28 is a detailed flow chart showing the use of a switch unit in step S203 in Fig. 22.

Figure 29 is a detailed flow chart showing a self-detecting method of a massage bath maintenance system in accordance with a preferred embodiment of the present invention.

FIG. 30 is a flow chart showing the first detailed detection method of step S303 in FIG.

FIG. 31 is a flow chart showing the second detailed detection method of step S303 in FIG.

Figure 32 is a flow chart showing the third detailed detection method of step S303 in Figure 29 .

FIG. 33 is a flow chart showing the first detailed detection method of step S310 in FIG.

Figure 34 is a flow chart showing the second detailed detection method of step S310 in Figure 29 .

35 is a flow chart showing a third detailed detection method of step S310 in FIG.

Figure 36 is a schematic view showing a third composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention.

Figure 37 is a schematic view showing a fourth composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention.

Figure 38 is a schematic view showing a fifth composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention.

Figure 39 is a schematic view showing a sixth composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention.

Fig. 40 is a detailed flow chart showing the use of a switch unit in the self-detection method of the massage bath maintenance system of the present invention.

The following description of various embodiments is presented to illustrate the specific embodiments The directional terms mentioned in the present invention, such as "upper", "lower", "before", "after", "left", "right", "inside", "outside", "side", etc., are merely references. The direction of the schema. Therefore, the directional terminology used is for the purpose of illustration and understanding of the invention. Representative elements or connection relationships represented by dashed lines in the various figures are optional or not.

Referring to FIG. 1, a schematic diagram of a massage bath maintenance system 100 in accordance with a first preferred embodiment of the present invention is shown. The massage bath maintenance system 100 is suitable for a massage bathing device 4000, which may be a jacuzzi or a massage pool or a swimming pool, The massage bath maintenance system 100 includes an operation panel unit 1100, at least one additional device 3000, at least one slave device 1700, a master device 1000, and an analysis unit 5510. Although the plurality of devices of the same level, such as a plurality of additional devices 3000 or a plurality of slave devices 1700, are included in the massage bath maintenance system 100, only the graphics of the single device are represented in the following figures, but the devices are not limited thereby. The number of assemblies.

Referring to FIG. 1 , the at least one additional device 3000 is used to actuate the massage bathing device 4000. In other embodiments, the at least one additional device 3000 may also be disposed in the at least one slave device 1700. The at least one slave control device 1700 is provided with a control unit 2100 for generating and transmitting at least one actuation message according to the at least one actuation state of the at least one attachment device 3000 corresponding to the massage bathing device 4000, the actuation message being an abnormal code or A physical value (such as a voltage or current value or a corresponding logical value) or a chemical value. The master device 1000 controls the at least one slave device 1700 to receive the at least one actuation message. The master device 1000 includes a log table 1011 and a work log collecting unit 1020. The work log collecting unit 1020 is configured to record the at least one actuating message transmitted by the at least one slave device 1700. In a work log table 1011.

The analyzing unit 5510 is configured to analyze the at least one action message in the work log table 1011 of the master device 1000 to determine whether the at least one additional device 3000 is in an abnormal state; in this embodiment, the analyzing The unit 5510 is configured to query or compare the corresponding content contained in a built-in table according to the at least one action message, thereby determining whether some specific components (such as the at least one additional device 3000) in the system have an abnormal state and/or an aging state. . In the first embodiment shown in FIG. 1, although the analyzing unit 5510 is an operable proximal or distal device disposed outside the main control device 1000, the proximal or distal device may be Such as a computer or server or hand The analysis unit 5510 can be one or a combination of a software body, a hardware body, and a firmware body. However, in other embodiments, the analysis unit 5510 can also be disposed on the main control unit. In the device 1000, the slave device 1700 or other devices, the present invention does not limit the installation position of the analysis unit 5510 as long as it can work in cooperation with the master device 1000. In addition, in other functions, the control unit 2100 of the at least one slave device 1700 can also generate and transmit the at least one action message to the master device 1000 or other slave controller according to at least one predetermined self-detection operation procedure. Device 1700. The master device 1000 generates at least one control message to the at least one slave device 1700 to command the control unit 2100 of the at least one slave device 1700 to generate and transmit the at least one actuation message. The master device 1000 can generate a notification message to the operator via the operation panel unit 1100 or the wireless communication network or the wired network according to the determination result of the at least one action message. In addition, the operator can also perform various operations on the slave device 1700 or the add-on device 1000 via the master device 1000 or set or receive an action message or an operation feedback message returned by each device.

Referring to Figures 1 and 2, a schematic view of a second preferred embodiment of the massage bath maintenance system 200 of the present invention is illustrated. The difference between the second preferred embodiment and the first preferred embodiment is that the second preferred embodiment adds at least one wireless communication transceiver device 1200, at least one second slave control device 2300, and a maintenance interface 1300. The at least one slave device 1700 in the first preferred embodiment is substantially a massage bath control unit 2000 (such as a SPA controller) in the second preferred embodiment. In the second preferred embodiment, the massage bath maintenance system 200 further selectively or not includes a cloud server 5000, so the cloud server 5000 and its connection line with the wireless communication transceiver 1200 are dotted. Painted. The cloud server 5000 can be respectively connected to the main control device 1100 and the at least one slave device via the at least one wireless communication transceiver 1200 1700 to perform remote debugging/maintenance work, wherein the massage bath maintenance system 200 can still work independently regardless of whether the cloud server 5000 is connected. The service interface 1300 can be one or both of JTAG or RESET.

1 and 2, which are schematic diagrams for representing the functional blocks of the components in the massage bath maintenance system 100, 200, but do not limit the actual physical location of the components, the master device 1000 can be associated with any slave control The device 1700, such as the massage bath control unit 2000, is integrated in the same device, or the main control device 1000 can be integrated in the same device as the above-described operation panel unit 1100.

See Figures 2 and 3, and Figure 3 is a schematic diagram showing the composition of the main control device 1000 in Figure 2. The main control device 1000 further includes a memory unit 1010 for storing the work log table 1011. The work log table 1011 is further configured to store the main control device 1000 and the at least one slave device 1700 (such as the massage bath control unit 2000). ) Communication records between. The master device 1000 may further or may not be provided with an analysis unit 5510 (shown in dashed lines). In the case where the main control device 1000 is connected to the cloud server 5000, the analyzing unit 5510 can be selectively disposed in the cloud server 5000 instead of being disposed in the main control device 1000. In another case where the master device 1000 is not connected to the cloud server 5000, the analysis unit may be selectively disposed in the master device 1000.

See Figures 2 and 4, and Figure 4 is a schematic diagram showing the composition of the cloud server 5000 in Figure 2. The cloud server 5000 includes at least one cloud database 5100, an authentication management component 5200, a device management component 5300, an instant messaging management component 5400, and a remote detection maintenance management component 5500. The remote detection maintenance management component 5500 includes the cloud server 5000. The analyzing unit 5510 is configured to store the corresponding serial number of the massage bathing device 4000. Referring to FIG. 2, FIG. 3 and FIG. 4, the at least one wireless communication transceiver 1200 is connected to the cloud server 5000, and the work log table 1011 is transmitted to the at least one cloud of the cloud server 5000 via the main control device 1000. The database 5100 is stored. The cloud server 5000 issues a command to the master device 1000 to collect the at least one action message from the at least one slave device 1700 (eg, the massage bath control unit 2000) and record the work message in the work log table 1011, and record the work log. The at least one cloud database 5100 stored in the main control device 1000 and/or returned to the cloud server 5000 via the main control device 1000 is stored for maintenance. The cloud server 5000 causes the remote detection maintenance management component 5500 to perform at least one predetermined remote detection maintenance management program 7000 according to the determination result of the at least one actuation message in the work log table 1011 by the analyzing unit 5510. (See Figure 18). The master device 1000 generates the at least one control message to the at least one slave device 1700 according to the at least one predetermined remote detection maintenance management program 7000 (see FIG. 18) to command the at least one slave device 1700. The control unit 2100 performs warm booting and detection, and the at least one slave device 1700 generates the at least one actuation message including the detection result. The master device 1000 performs at least one maintenance operation on the at least one slave device 1700 according to the at least one predetermined remote detection maintenance management program 7000 (see FIG. 18), and after executing the at least one maintenance operation, commands The control unit 2100 of the at least one slave device 1700 performs detection, and the at least one slave device 1700 generates the at least one action message including the detection result, wherein the at least one maintenance operation includes incorrect setting correction, cold boot, and original A combination operation of at least one or more of code refill and program version update.

See Figures 1 and 5, and Figure 5 is a schematic diagram showing the composition of the operation panel unit 1100 in Figures 1 and 2. The operation panel unit 1100 is electrically connected to the main control device 1000 and has a display screen 1110 for displaying the notification message.

Referring to Fig. 6, a schematic diagram showing the composition of each additional device 3000 in Figs. 1 and 2 is shown. The attachment 3000 includes a first attachment 3100 and a second attachment 3200. The first attachment device 3100 includes a zone water spray device 3110, an automatic water supply device 3120, a photographing device 3130, an infrared device 3140, an ultrasonic device 3150, a pump 3160, and a heater 3170. The second attachment 3200 includes a light control device 3210, a blower 3220, a heater 3230, a pumping valve 3240, a pump 3250, a sensor 3260, an ozone generator 3270, and a motor 3280.

Referring to FIG. 7, a schematic diagram of the composition of the second slave device 2300 in FIG. 2 is shown. The second slave device 2300 includes an external light control device 2310, an internet device 2320, a video playback device 2330, a voice and music device 2340, and an external storage device 2350.

Referring to Figures 1 and 8, Figure 8 is a schematic illustration of a massage bath maintenance system 300 in accordance with a third preferred embodiment of the present invention. The difference between the third preferred embodiment and the first preferred embodiment is that a detection and feedback device 2200 is added to the third preferred embodiment, wherein the control unit 2100 controls the detection and feedback device 2200 to An additional device 3000 performs detection and generates the at least one actuation message including the detection result for transmission to the main control device 1000.

Referring to Figure 9, a schematic view of a massage bath maintenance system in accordance with a fourth preferred embodiment of the present invention is illustrated. The difference between the fourth preferred embodiment and the third preferred embodiment is that the fourth preferred embodiment adds at least one wireless communication transceiver device 1200, at least one second slave control device 2300, and a maintenance interface 1300. The fourth preferred embodiment may also optionally or not include a cloud server 5000 (shown in dashed lines). Other elements similar to the second preferred embodiment and the first preferred embodiment, please refer to the foregoing description for related content.

Please refer to FIGS. 9 and 10 for a schematic diagram showing the first composition of the massage bath control unit 2000 and each of the second attachment devices of the massage bath maintenance system 400 of FIG. The first A composition form includes a power source 1400, a massage bath control unit 2000, and a plurality of second attachment devices 3210 to 3280 (here, each device in the second attachment device 3200 of FIG. 6 is taken as an example, but is not Optionally, at least one additional device 3000 as shown in FIG. 2 includes both the first additional device 3100 and the second additional device 3200. The massage bath control unit 2000 includes a control unit 2100, a detection feedback device 2200, and a temperature measurement deviation confirmation device 2210. The detection feedback device 2200 includes at least one switching unit and at least one sensing unit 2220. The at least one switching unit can be a relay. The at least one switch unit is controlled by the control unit 2100 to turn on or off a power supply 1400 that supplies the at least one second add-on device. In this embodiment, the at least one switch unit is composed of four switch units, the at least one A sensing unit 2220 includes four sensing units 2220 respectively disposed between the switching units and the plurality of second additional devices 3200 (including the heater 3230, the ozone generator 3270, the motor 2380, and the light control device 3210). Positionally detecting a specific physical value between the switching units and the plurality of second additional devices 3200, and transmitting the measured specific physical values to the control unit 2100, the control unit 2100 determining the specific The physical value is used as the detection result to generate the at least one actuation message and to provide the at least one actuation message to the main control device 1000. The specific physical value described above is a current value or a voltage determination logic value. 11 is a schematic diagram showing the composition of the temperature measurement deviation confirmation device 2210 in FIG. 10, the temperature measurement deviation confirmation device 2210 includes a temperature sensor 2211 and a voltage detection unit 2212, and the temperature sensor 2211 is used to The data measured by the voltage verification unit 2212 determines whether the temperature sensor 2211 is abnormal.

9 and 12, FIG. 12 is a schematic diagram showing a second composition state of the massage bath control unit 2000 and each second attachment device of the massage bath maintenance system 400 of FIG. 9, which is the same as that of FIG. A compositional difference is that the Detective of the massage bath control unit 2000 The measuring feedback device 2200 sets a sensing unit 2220 between the plurality of second additional devices 3200 (including the heater 3230, the ozone generator 3270, the motor 2380, and the light control device 3210) and the control unit 2100 to detect a specific physical value of the plurality of second additional devices 3200, and transmitting the measured specific physical value to the control unit 2100, wherein the control unit 2100 uses the measured specific physical value as the detection result to generate the at least one actuation And providing the at least one actuation message to the master device 1000 as shown in FIG.

9 and FIG. 13 , FIG. 13 is a schematic diagram showing a third composition state of the massage bath control unit 2000 and each second attachment device of the massage bath maintenance system 400 of FIG. 9 , and FIG. 10 The composition of the massage bath control unit 2000 is such that the sensing unit 2200 is disposed between the plurality of switch units and the power source 1400 to detect the supply of the plurality of units. a specific physical value between the power supply 1400 of the second add-on device 3200 (including the heater 3230, the ozone generator 3270, the motor 2380, and the light control device 3210) and the at least one second add-on device 3200, and transmitting the measured specific physics The value is sent to the control unit 2100, and the control unit 2100 uses the measured specific physical value as the detection result to generate the at least one actuation message and provide the at least one actuation message to the main control device 1000. The temperature measurement deviation confirmation device 2210 of the detection and feedback device 2200 is electrically connected to the control unit 2100 for detecting a temperature state of a thermometer to generate the detection result, and the control unit 2100 generates and transmits the detection result according to the detection result. The at least one actuation state is to the master device 1000.

Referring to Figures 9 and 14, Figure 14 is a schematic illustration of a massage bath maintenance system 500 in accordance with a fifth preferred embodiment of the present invention. The difference between the fifth preferred embodiment and the fourth preferred embodiment of FIG. 9 is that the massage bath control unit and the second additional device are not provided in the fifth preferred embodiment but at least one first slave is added. Control device 2400. Each of the at least one first The slave device 2400 includes a control unit 2100, a detection feedback device 2200, and at least a first additional device 3100. In the preferred embodiment, each of the first slave devices 2400 is formed by each of the first additional devices 3100 (see FIG. 6), the control unit 2100, and the detection feedback device 2200. The control unit 2100 and the detection and feedback device 2200 are the same as the above embodiments, and are not described again.

See Fig. 15, which is a schematic diagram showing the composition of the main control device 1000 and the plurality of first slave devices 2400 of the massage bath maintenance system 500 of Fig. 14. In the present composition, a portion of the at least one first attachment device 3100 (including the camera device 3130, the infrared device 3140, the pump 3160, and the heater 3170) is combined with a detection feedback device 2200 and a control unit 2100. To form a plurality of first slave devices 2400, and another portion of the at least one first device 3100 (including the zone water spray device 3110, the automatic water supply device 3120) only needs one detection feedback device because the control unit is built in. The 2200 combination can form a plurality of first slave devices 2400, and is electrically connected to the master device 1000 and the power source 1400.

Please refer to FIG. 16 and FIG. 17, FIG. 16 is a first control timing diagram of each massage bath maintenance system 100, 200, 300, 400, 500 of the present invention, and FIG. 17 is a second control diagram of each massage bath maintenance system 100, 200, 300, 400, 500 of the present invention. Timing diagram, and for the convenience of understanding the description of each of the above timing diagrams, please refer to the component numbers drawn in Figures 2, 9 and 14. The first control timing diagram and the second control timing diagram shown in FIG. 16 and FIG. 17 respectively represent two timing control modes, and one is that the remote detection maintenance manager is initiated by the remote end (cloud server 5000). Another representative actively initiates the remote detection maintenance management program by the near end (master device 1000).

First, as shown in FIG. 16, when the remote cloud server 5000 initiates the remote detection maintenance management program 7000, the service starts to execute the remote detection maintenance management program 7000. The remote detection maintenance management program 7000 then requests a sequence number of the corresponding massage bath device 4000 from the cloud database 5100. Next, the serial number of the massage bathing device 4000 is returned. Next, the remote detection maintenance management program 7000 confirms the validity of the serial number of the corresponding massage bathing device 4000. Then, the remote detection maintenance management program 7000 establishes a remote connection between the main control device 1000 and the cloud server 5000. Then, the cloud server 5000 finds the corresponding master device 1000 through a network such as the Internet and issues a connection request. Next, the master device 1000 authenticates and establishes a connection. Next, the cloud server 5000 confirms the connection. Then, the remote detection maintenance management program 7000 enters the collection mode of the work log table 1011 or other operation modes such as a RESET command or a JTAG refill operation or an update code download. Next, the cloud server 5000 requests the master device 1000 to return various data or actions of the work log table 1011 and various operations or commands. Then, the main control device 1000 controls at least one slave device 1700 and at least one additional device 3000 to directly or indirectly operate, such as performing detection. Next, the slave device 1700 and the add-on device 3000 perform an operation according to the above control, such as performing detection. Then, the adding device 3000 generates at least one detection result such as representative detection data or status, and the slave device 1700 generates at least one action message including the at least one detection result as work log data. Then, the main control device 1000 receives the at least one actuation message (work log data) to perform data aggregation of the work log table 1011. Next, the main control device 1000 encapsulates the information of the work log table 1011 into an XML, JSON, or the like format. Then, the cloud server 5000 performs information transfer of the work log table 1011. Next, the information of the work log table 1011 is stored in the cloud database 5100. Next, the cloud database 5100 confirms. Next, the analyzing unit 5510 performs a message analysis and processing flow of the work log table 1011.

Figure 17 illustrates the remote detection maintenance management program 7000 initiated by the near end. first First, the slave device 1700 generates the work log information and the message as described above, and includes the action message of the at least one detection result. The actuation message of the at least one detection result includes a record generated as shown in Fig. 19 and a record of daily detection. Then, the master device 1000 requests the slave device 1700 to provide the work log information and information. Then, the slave device 1700 returns the data and message of the work log. Then, the main control device 1000 requests the cloud server 5000 to upload a service such as a work log table through the Internet through the information API and the resource API. Then, the cloud server 5000 confirms the message. Then, the cloud server 5000 confirms or rejects. Next, the master device 1000 sends a message encapsulated in XML, JSON format, such as the work log table. Next, the cloud server 5000 confirms the message and forwards the message to the message incoming management and queue management 5410 queue order. Then, the cloud database 5100 performs database management. The cloud database then confirms the message or other message.

Figure 18 is a flow chart showing the massage bath maintenance method of the massage bath maintenance system of the present invention. In step S01, the serial number of the massage bathing device 4000 is obtained. Next, in step S02, it is determined whether the serial number is valid. In step S02, if no, step S25 is executed to notify the person to attend the repair. In step S02, if yes, then, in step S03, a connection between the massage bathing device 4000 and the cloud server 5000 is established. Next, in step S04, it is confirmed whether the connection is successful. In step S04, if no, step S25 is executed to notify the person to attend the repair. In step S04, if yes, in step S05, the main control device 1000 starts the query work log mode. Next, in step S06, the analyzing unit 5510 analyzes the at least one detection message to determine whether the at least one additional device 3000 has an abnormal state. Next, in step S07, it is confirmed whether the at least one slave device 1700 sets an error. In step S07, if no, step S12 is executed to confirm whether the peripheral communication is abnormal. In step S07, if yes, step S08 is executed to correct the at least one slave device according to the setting of the cloud server 5000. 1700 settings. Next, in step S09, at least one actuation message is generated. Next, in step S10, it is confirmed whether or not it is normal. In step S10, if no, step S25 is executed to notify the person to attend the repair. In step S10, if yes, step S11 is executed to confirm whether there is another failure. In step S11, if no, step S26 is executed and the method ends. In step S11, if yes, step S12 is executed to confirm whether the peripheral communication is abnormal. In step S12, if no, step S20 is executed to reinstall the existing program. In step S12, if yes, step S13 is performed, and the warm-up command is generated from the detection log. Next, in step S14, at least one actuation message is generated. Next, in step S15, it is confirmed whether or not it is normal. In step S15, if yes, step S19 is executed to confirm whether there is another failure. In step S15, if no, step S16 is performed, and the cold boot command generates a self-detect log. Next, in step S17, at least one actuation message is generated. Next, in step S18, it is confirmed whether or not it is normal. In step S18, if no, step S25 is executed to notify the person to attend the repair. In step S18, if yes, step S19 is executed to confirm whether there is another failure. In step S19, if no, step S26 is executed and the method ends. In step S19, if yes, step S20 is executed to reinstall the existing program. Next, in step S21, it is confirmed whether or not it is normal. In step S21, if yes, step S26 is executed and the method ends. In step S21, if no, step S22 is performed to confirm whether the version is too old. In step S22, if no, step S25 is executed to notify the person to attend the repair. In step S22, if yes, step S23 is executed to update the program version. Then, step S27 is executed to generate at least one action message. Next, step S24 confirms whether or not it returns to normal. In step S24, if yes, the method ends. In step S24, if no, step S25 is executed to notify the person to attend the repair. The remote detection maintenance management program 7000 is shown from steps S07 to S27.

Figure 19 is a flow chart showing the detection method of the massage bath maintenance system of the present invention. First, in step S101, the massage bath maintenance system is powered on. Next, in step S102, the CPU initialization. Next, in step S103, the self-test mode is entered. Next, in step S104, the operation mode is entered, and normal recording and abnormal recording are generated at the same time. Next, in step S105, the operation/detection flow of the heater is performed and a record is generated. Next, in step S106, the operation/detection flow of the motor is executed and a record is generated. In step S107, the operation/detection process of the light control device is executed and a record is generated. Next, in step S108, the operation/detection flow of the other second additional devices is performed and a record is generated. Then, if the massage bath maintenance system is continuously used, step S104 is repeatedly performed; if the massage bath maintenance system is not used, step S109 is performed, and the massage bath maintenance system is shut down.

20 is a schematic view showing a first composition state of the massage bath control unit 2000 of the massage bath maintenance system of the present invention. In this aspect, the detection feedback device 2200 includes at least one switching unit and at least one sensing unit 2220. In the present invention, the at least one switching unit includes a first switching unit 2010, a second switching unit 2020, and a third switching unit 2030, and each of the above-described switching units 2010, 2020, and 2030 may be a relay. The at least one sensing unit 2220 includes two sensing units 2220 (ie, a first sensing unit 2220 and a second sensing unit 2220), wherein the second sensing unit 2220 is a photocoupler. In this aspect, the heater 3230 is taken as an example. The control unit 2100 is connected to the first switch unit 2010, the first switch unit 2010 is connected to the second switch unit 2020, and the second switch unit 2020 is connected to the first end of the first sensing unit 2220, the first The second end of the sensing unit 2220 is connected to the control unit 2100, and the third end of the first sensing unit 2220 is connected to the first end of the second additional device 3200 (ie, the heater 3230), and the second additional device 3200 The second end is connected to the third switch unit 2030, and the third switch unit 2030 is connected to the control unit 2100. The first end of the photocoupler 2220 is connected to the control unit 2100. The second end of the photocoupler 2220 is connected to the first end of the first sensing unit 2220, and the third end of the photocoupler 2220 is connected to the second end. The second end of the attachment 3200.

Figure 21 is a schematic view showing the second composition of the massage bath control unit of the massage bath maintenance system of the present invention. The difference between the second composition state and the first composition state described in FIG. 20 is that the second composition state lacks the third switching unit 2030 and the wiring manner is changed correspondingly. The control unit 2100 is connected to the first switch unit 2010. The first switch unit 2010 is connected to the first end of the first sensing unit 2220, and the second end of the first sensing unit 2220 is connected to the control unit 2100. The third end of the first sensing unit 2220 is connected to the first end of the second adding device 3200, the second end of the second adding device 3200 is connected to the second switching unit 2020, and the second switching unit 2020 is connected to the control unit 2100. The first end of the photocoupler 2220 is connected to the control unit 2100. The second end of the photocoupler 2220 is connected to the first end of the first sensing unit 2220, and the third end of the photocoupler 2220 is connected to the second end. The second end of the attachment 3200.

Figure 22 is a schematic flow chart showing a self-detecting method of a massage bath maintenance system in accordance with a preferred embodiment of the present invention. First, in step S201, the switching unit turns on the test flow. Next, in step S202, the aging and fault testing process of the additional device is performed. Next, in step S203, the switching unit does not conduct the test flow. Finally, in step S204, the method ends.

Fig. 23 is a detailed flow chart showing the use of three switching units in step S201 in Fig. 22. In this flow, the continuity test procedure when there are three switching units is explained in detail. First, in step S601, the first switching unit, the second switching unit, and the third switching unit are not turned on. Next, in step S602, the first switching unit is turned on. Next, in step S603, the second switching unit is turned on. Next, in step S604, the third switching unit is turned on. Next, in step S605, it is confirmed whether at least one of the first switching unit, the second switching unit, and the third switching unit can be normally turned on. In step S605, if yes, step S606 is performed to confirm that the first switch unit, the second switch unit, and the third switch unit are at least three of them. One can be turned on normally. Next, in step S607, the work log table 1011 is recorded and/or displayed on the display screen 1110. The order of steps 602-604 may be performed before and after transformation as needed. In the step S605, if no, the additional device 3000 and/or the massage bath control unit 2000 need to be replaced, and the at least one detection message is recorded in the work log 1011 and/or displayed on the display screen 1110.

Fig. 24 is a detailed flow chart showing the use of three switch units in step S203 in Fig. 22. In this flow, the non-conduction test flow when there are three switch units is explained in detail. First, in step S501, the first switching unit, the second switching unit, and the third switching unit are turned on. Next, in step S502, the first switching unit is not turned on. Next, in step S503, the second switching unit is not turned on. Next, in step S504, the third switching unit is not turned on. Next, in step S505, it is confirmed whether at least one of the first switching unit, the second switching unit, and the third switching unit is normally non-conductive. In step S505, if yes, step S506 is performed to confirm that at least one of the first switching unit, the second switching unit, and the third switching unit can be normally non-conducting. Next, in step S507, the work log table 1011 is recorded and/or displayed on the display screen 1110. The sequence of steps 502-504 may be performed before and after transformation as needed. In the step S505, if no, the additional device 3000 and/or the massage bath control unit 2000 need to be replaced, and the at least one detection message is recorded in the work log 1011 and/or displayed on the display screen 1110.

Fig. 25 is a detailed flow chart showing the use of the two switching units in step S201 in Fig. 22. In this flow, the continuity test procedure when there are two switching units is explained in detail. First, in step S608, the first switching unit and the second switching unit are not turned on. Next, in step S609, the first switching unit is turned on. Next, in step S610, the second switching unit is turned on. Next, in step S611, it is confirmed whether at least one of the first switching unit and the second switching unit can be normally turned on. In step S611, if yes, step S612 is performed to confirm that at least one of the first switching unit and the second switching unit can be normally turned on. Next, in step S613, the work log table 1011 is recorded and/or displayed on the display screen 1110. The sequence of steps 609-610 may be performed before and after transformation as needed. In the step S611, if no, the additional device 3000 and/or the massage bath control unit 2000 need to be replaced, and the at least one detection message is recorded in the work log 1011 and/or displayed on the display screen 1110.

Fig. 26 is a detailed flow chart showing the use of the two switching units in step S203 in Fig. 22. In this flow, the non-conduction test flow when there are two switch units is explained in detail. First, in step S508, the first switching unit and the second switching unit are turned on. Next, in step S509, the first switching unit is not turned on. Next, in step S510, the second switching unit is not turned on. Next, in step S511, it is confirmed whether at least one of the first switching unit and the second switching unit can be normally non-conductive. In step S511, if yes, step S512 is performed to confirm that at least one of the first switching unit and the second switching unit can be normally non-conductive. Next, in step S513, the work log table 1011 is recorded and/or displayed on the display screen 1110. The order of steps 509-510 may be performed before and after transformation as needed. In the step S511, if no, the additional device 3000 and/or the massage bath control unit 2000 need to be replaced, and the at least one detection message is recorded in the work log 1011 and/or displayed on the display screen 1110.

Fig. 27 is a detailed flow chart showing the use of a switch unit in step S201 in Fig. 22. In this flow, the continuity test procedure when there is only one switching unit is explained in detail. First, in step S614, the first switching unit is not turned on. Next, in step S615, the first switching unit is turned on. Next, in step S616, it is confirmed whether the first switching unit can be normally turned on. In step S616, if yes, step S617 is executed to confirm that the first switching unit can be normally turned on. Next, in step S618, the work log table 1011 is recorded and/or displayed on the display screen 1110. In step S616, if not, it indicates that the additional device 3000 and/or the massage bath control unit 2000 need to be replaced, and the at least one detection message is generated and recorded in the work log 1011 and/or displayed on the display screen 1110.

Fig. 28 is a detailed flow chart showing the use of a switch unit in step S203 in Fig. 22. In this flow, the non-conduction test flow when there is only one switch unit is explained in detail. First, in step S514, the first switching unit is turned on. Next, in step S515, the first switching unit is not turned on. Next, in step S516, it is confirmed whether the first switching unit can be normally turned off. In step S516, if yes, step S517 is executed to confirm that the first switching unit can be normally non-conductive. Next, in step S518, the work log table 1011 is recorded and/or displayed on the display screen 1110. In step S516, if not, it indicates that the additional device 3000 and/or the massage bath control unit 2000 need to be replaced, and the at least one detection message is generated and recorded on the work log 1011 and/or displayed on the display screen 1110.

Figure 29 is a detailed flow chart showing a self-detecting method of a massage bath maintenance system in accordance with a preferred embodiment of the present invention. First, in step S301, the control unit 2100 performs at least one continuity test procedure of the at least one switching unit. Next, in step S302, the work log table 1011 is recorded and/or displayed on the display screen 1110. Next, in step S303, it is confirmed whether at least one of the at least one switching unit can be normally turned on. In step S303, if no, step S311 is executed to generate the at least one detection message recorded in the work log 1011 and/or displayed on the display screen 1110. Next, in step S314, the method ends. In step S303, if yes, step S304 is performed, and the analyzing unit 2100 calculates the at least one additional device according to the work log table 1011. An aging slope of current and time of 3000. Next, in step S305, the analyzing unit 2100 determines, according to the aging slope, whether the at least one additional device 3000 needs to be replaced. In step S305, if necessary, step S306 is executed to generate the at least one detection message recorded in the work log 1011 and/or displayed on the display screen 1110. Next, in step S307, the analyzing unit 2100 confirms whether the current of the at least one additional device 3000 is less than a predetermined current. In step S305, if not, step S307 is performed. In step S307, if no, step S312 is executed to generate the at least one detection message recorded in the work log 1011 and/or displayed on the display screen 1110. Next, in step S314, the method ends. In step S307, if yes, step S308 is performed, and the control unit performs at least one non-conduction test flow of the at least one switching unit. Next, in step S309, the at least one detection message is generated and recorded in the work log 1011 and/or displayed on the display screen 1110. Next, in step S310, it is confirmed whether at least one of the at least one switching unit is normally non-conductive. In step S310, if no, step S313 is executed to generate the at least one detection message recorded in the work log 1011 and/or displayed on the display screen 1110. Next, in step S314, the method ends. In step S310, if yes, step S314 is executed and the method ends.

FIG. 30 is a flow chart showing the first detailed detection method of step S303 in FIG. First, step S30301 is executed to disable the first switching unit 2010, the second switching unit 2020, and the third switching unit 2030. Next, in step S30302, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30303, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30303, if yes, step S30315 is executed to generate an alarm message (the first switch unit 2010, the second switch unit 2020 and the third switch unit 2030 are all short-circuited) to the work log table 1011, which is displayed on The display screen 1110. Then, step S30314 is executed, and step S304 is performed. In step S30303, if not, then Step S30304 is executed to turn on the third switching unit 2030. Then, in step S30305, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30306, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30306, if yes, step S30316 is executed to generate an alarm message (the first switch unit 2010 and the second switch unit 2020 are short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S30307 is executed to turn on the second switching unit 2020. In step S30306, if not, step S30307 is executed to turn on the second switching unit 2020. Then, in step S30308, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30309, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30309, if yes, step S30317 is executed to generate an alarm message (the first switch unit 2010 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S30310 is performed to turn on the first switching unit 2010. In step S30309, if not, step S30310 is executed to turn on the first switching unit 2010. Then, in step S30311, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30312, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30312, if not, step S30318 is executed to generate an alarm message (one or more of the first switch unit 2010, the second switch unit 2020, and the third switch unit 2030 are open) to the work. The log table 1011 is displayed on the display screen 1110. Next, step S30314 is followed to execute step S304. In step S30312, if yes, step S30313 is executed, the first detection flow ends, and is stored in the work log table 1011. Next, step S30314 is followed to execute step S304.

FIG. 31 is a flow chart showing the second detailed detection method of step S303 in FIG. First, step S30319 is performed, the first switch unit 2010 and the second switch are not turned on. Unit 2020 and the third switching unit 2030. Next, in step S30320, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30321, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30321, if yes, step S30333 is executed to generate an alarm message (the first switch unit 2010, the second switch unit 2020 and the third switch unit 2030 are short-circuited) to the work log table 1011, which is displayed on The display screen 1110. Next, step S30332 is performed, and step S304 is performed. In step S30321, if not, step S30322 is executed to turn on the second switching unit 2020. Next, in step S30323, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30324, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30324, if yes, step S30334 is executed to generate an alarm message (the first switch unit 2010 and the third switch unit 2030 are short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S30325 is performed to turn on the first switching unit 2010. In step S30324, if not, step S30325 is executed to turn on the first switching unit 2010. Then, in step S30326, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30327, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30327, if yes, step S30335 is executed to generate an alarm message (the third switch unit 2030 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S30328 is executed to turn on the third switching unit 2030. In step S30327, if not, step S30328 is executed to turn on the third switching unit 2030. Then, in step S30329, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30330, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30330, if not, step S30336 is executed to generate an alarm message (the first switch unit 2010, the second switch unit 2020, and the One or more of the third switching units 2030 are open circuited to the work log table 1011 and displayed on the display screen 1110. Next, step S30332 is followed to execute step S304. In step S30330, if yes, step S30331 is performed, and the second detection flow ends and is stored in the work log table 1011. Next, step S30332 is followed to execute step S304.

Figure 32 is a flow chart showing the third detailed detection method of step S303 in Figure 29 . First, step S30337 is executed to disable the first switching unit 2010, the second switching unit 2020, and the third switching unit 2030. Next, in step S30338, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30339, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30339, if yes, step S30351 is executed to generate an alarm message (the first switch unit 2010, the second switch unit 2020 and the third switch unit 2030 are all short-circuited) to the work log table 1011, which is displayed on The display screen 1110. Then, step S30350 is performed, and step S304 is performed. In step S30339, if not, step S30340 is executed to turn on the first switching unit 2010. Then, in step S30341, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30342, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30342, if yes, step S30352 is executed to generate an alarm message (the second switch unit 2020 and the third switch unit 2030 are short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S30343 is performed to turn on the third switching unit 2030. In step S30342, if not, step S30343 is executed to turn on the third switching unit 2030. Then, in step S30344, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30345, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30345, if yes, step S30353 is executed to generate an alarm message (the second switching unit 2020 is short-circuited) The work log table 1011 is displayed on the display screen 1110. Next, step S30346 is performed to turn on the second switching unit 2020. In step S30345, if not, step S30346 is executed to turn on the second switching unit 2020. Next, in step S30347, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S30348, the at least one sensing unit 2220 determines whether there is current or voltage. In step S30348, if not, step S30354 is executed to generate an alarm message (one or more of the first switch unit 2010, the second switch unit 2020, and the third switch unit 2030 are open) to the work. The log table 1011 is displayed on the display screen 1110. Next, step S30350 is followed to execute step S304. In step S30348, if yes, step S30349 is performed, and the third detection flow ends and is stored in the work log table 1011. Next, step S30350 is followed to execute step S304.

The detection process of the above three steps S303 selects a different process from the previous time and the previous two times to detect each time the power is turned on.

FIG. 33 is a flow chart showing the first detailed detection method of step S310 in FIG. First, step S31001 is performed to turn on the first switching unit 2010, the second switching unit 2020, and the third switching unit 2030. Next, in step S31002, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31003, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31003, if not, step S31015 is executed to generate an alarm message (one or more of the first switch unit 2010, the second switch unit 2020, and the third switch unit 2030 are open) to the work. The log table 1011 is displayed on the display screen 1110. Then, step S31014 is performed, and step S313 is performed. In step S31003, if yes, step S31004 is executed, and the third switching unit 2030 is not turned on. Then, in step S31005, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. then, Step S31006, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31006, if not, step S31055 is performed, and the second switching unit 2020 is not turned on. Next, step S31056 is performed to disable the first switching unit 2010. Next, step S31014 is performed, and step S313 is performed. In step S31006, if yes, step S31016 is executed to generate an alarm message (the third switch unit 2030 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Then, step S31007 is executed, and the second switching unit 2020 is not turned on. Then, in step S31008, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31009, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31009, if not, step S31056 is performed, and the first switching unit 2010 is not turned on. Next, step S31014 is performed, and step S313 is performed. In step S31009, if yes, step S31017 is executed to generate an alarm message (the second switch unit 2020 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Then, step S31010 is performed, and the first switching unit 2010 is not turned on. Then, in step S31011, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31012, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31012, if yes, step S31018 is executed to generate an alarm message (the first switch unit 2010 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S31014 is followed, and step S313 is performed. In step S31012, if not, step S31013 is performed, the first detection flow ends, and is stored in the work log table 1011. Next, step S31014 is followed, and step S313 is performed.

Figure 34 is a flow chart showing the second detailed detection method of step S310 in Figure 29 . First, step S31019 is performed to turn on the first switching unit 2010, the second switching unit 2020, and the third switching unit 2030. Next, in step S31020, the at least one sensing unit The 2220 feeds back the read message to the analysis unit 5510. Next, in step S31021, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31021, if not, step S31033 is executed to generate an alarm message (one or more of the first switch unit 2010, the second switch unit 2020, and the third switch unit 2030 are open) to the work. The log table 1011 is displayed on the display screen 1110. Then, step S31032 is performed, and step S313 is performed. In step S31021, if yes, step S31022 is performed, and the second switching unit 2020 is not turned on. Then, in step S31023, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31024, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31024, if not, step S31057 is performed, and the first switching unit 2010 is not turned on. Next, step S31058 is performed to not turn on the third switching unit 2030. Next, step S31032 is performed, and step S313 is performed. In step S31024, if yes, step S31034 is executed to generate an alarm message (the second switch unit 2020 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Then, step S31025 is performed, and the first switching unit 2010 is not turned on. Next, in step S31026, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31027, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31027, if not, step S31058 is performed to not turn on the third switching unit 2030. Next, step S31032 is performed, and step S313 is performed. In step S31027, if yes, step S31035 is executed to generate an alarm message (the first switch unit 2010 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S31028 is executed to not turn on the third switching unit 2030. Then, in step S31029, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31030, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31030, if yes, step S31036 is executed to generate one. The alarm message (the second switch unit 2020 is shorted) to the work log table 1011 is displayed on the display screen 1110. Next, step S31032 is followed, and step S313 is performed. In step S31030, if not, step S31031 is performed, and the second detection flow ends and is stored in the work log table 1011. Next, step S31032 is followed, and step S313 is performed.

35 is a flow chart showing a third detailed detection method of step S310 in FIG. First, step S31037 is executed to turn on the first switch unit 2010, the second switch unit 2020, and the third switch unit 2030. Next, in step S31038, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31039, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31039, if not, step S31051 is executed to generate an alarm message (one or more of the first switch unit 2010, the second switch unit 2020, and the third switch unit 2030 are open) to the work. The log table 1011 is displayed on the display screen 1110. Then, step S31050 is performed, and step S313 is performed. In step S31039, if yes, step S31040 is performed, and the first switching unit 2010 is not turned on. Then, in step S31041, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31042, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31042, if not, step S31059 is performed to disable the third switching unit 2030. Next, step S31060 is performed to disable the second switching unit 2020. Next, step S31050 is performed, and step S313 is performed. In step S31042, if yes, step S31052 is executed to generate an alarm message (the first switch unit 2010 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S31043 is performed to not turn on the third switching unit 2030. Then, in step S31044, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31045, the at least one sensing unit 2220 determines whether there is current or voltage. in In step S31045, if not, step S31060 is performed, and the second switching unit 2020 is not turned on. Next, step S31050 is performed, and step S313 is performed. In step S31045, if yes, step S31053 is executed to generate an alarm message (the third switch unit 2030 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S31046 is performed to disable the second switching unit 2020. Then, in step S31047, the at least one sensing unit 2220 feeds back the read message to the analyzing unit 5510. Next, in step S31048, the at least one sensing unit 2220 determines whether there is current or voltage. In step S31048, if yes, step S31054 is executed to generate an alarm message (the second switch unit 2020 is short-circuited) to the work log table 1011, which is displayed on the display screen 1110. Next, step S31050 is followed, and step S313 is performed. In step S31048, if not, step S31049 is performed, and the third detection flow ends and is stored in the work log table 1011. Next, step S31050 is followed, and step S313 is performed.

The detection process of the above three steps S310 selects a different process from the previous time and the previous two times to detect each time the power is turned off.

Refer to Figures 36 to 39. Figure 36 is a schematic view showing a third composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention. Figure 37 is a schematic view showing a fourth composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention. Figure 38 is a schematic view showing a fifth composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention. Figure 39 is a schematic view showing a sixth composition of a massage bath control unit of a massage bath maintenance system in accordance with a preferred embodiment of the present invention. The difference between the above four embodiments is that the motor 3280, the ozone generator 3270, and the light control device 3210 (having a dimmer 2050 and a version without the dimmer 2050) are respectively connected. The difference between each of the above four embodiments and the second composition The difference is that the first embodiment of the 36th to 39th embodiments only has the first switching unit 2010. The control unit 2100 is connected to the first switch unit 2010. The first switch unit 2010 is connected to the first end of the first sensing unit 2220, and the second end of the first sensing unit 2220 is connected to the control unit 2100. The third end of the first sensing unit 2220 is connected to the first end of the second adding device 3200 (the motor 3280, the ozone generator 3270 and the light control device 3210), and the second end of the second adding device 3200 is connected to the control unit 2100. The first end of the photocoupler 2220 (just like the second sensing unit) is connected to the control unit 2100. The second end of the photocoupler 2220 is connected to the first end of the first sensing unit 2220. The photocoupler 2220 The third end is connected to the second end of the second attachment 3200.

Fig. 40 is a detailed flow chart showing the self-detection method of the massage bath maintenance system of the present invention in a switch unit. First, in step S401, the control unit 2100 performs the first switching unit continuity test procedure. Next, in step S402, the at least one detection message is generated and recorded in the work log table 1011 and/or displayed on the display screen 1110. Next, in step S403, it is confirmed whether the first switching unit can be normally turned on. In step S403, if no, step S413 is executed to generate the at least one detection message and record it in the work log table 1011 and/or display it on the display screen 1110. Next, in step S412, the method ends. In step S403, if yes, step S404 is performed, and the control unit 2100 executes the first switching unit non-conduction test flow. Next, in step S405, the at least one detection message is generated and recorded in the work log table 1011 and/or displayed on the display screen 1110. Next, in step S406, it is confirmed whether the first switching unit can be normally not turned on. In step S406, if no, step S413 is executed to generate the at least one detection message and record it in the work log table 1011 and/or display it on the display screen 1110. Next, in step S412, the method ends. In step S406, if yes, step S407 is performed, and the analyzing unit 2100 confirms whether the current of the at least one additional device 3000 is less than a predetermined current. In step S407, if no, the step is executed. In step S413, the at least one detection message is generated and recorded in the work log table 1011 and/or displayed on the display screen 1110. Next, in step S412, the method ends. In step S407, if yes, step S408 is performed, and the analyzing unit 2100 calculates an aging slope of current and time of the at least one additional device 3000 according to the work log table 1011. Next, in step S409, the analyzing unit determines whether the at least one additional device needs to be replaced according to the aging slope. In step S409, if yes, step S413 is executed to generate the at least one detection message and record it in the work log table 1011 and/or display it on the display screen 1110. Next, in step S412, the method ends. In step S409, if no, step S410 is executed to confirm whether there is a change in the frequency of the current of the at least one additional device 3000. In step S410, if yes, step S413 is executed to generate the at least one detection message and record it in the work log table 1011 and/or display it on the display screen 1110. Next, in step S412, the method ends. In step S410, if no, step S411 is executed to confirm whether there is a change in the low frequency of the current of the at least one additional device 3000. In step S411, if yes, step S413 is executed to generate the at least one detection message and record it in the work log table 1011 and/or display it on the display screen 1110. Next, in step S412, the method ends. In step S411, if no, step S412 is executed and the method ends.

With the massage bath maintenance system and method of the present invention, it is possible to quickly know the operational status of the overall system and to perform prompt and appropriate maintenance.

The above is only a preferred embodiment of the present invention, and it should be noted that those skilled in the art can also make several improvements and retouchings without departing from the principles of the present invention. These improvements and retouchings should also be considered as The scope of protection of the present invention.

300‧‧‧Massage bath maintenance system

1000‧‧‧Master control unit

1011‧‧‧Work log table

1100‧‧‧Operation panel unit

1020‧‧‧Work log aggregation unit

1700‧‧‧ slave control device

2100‧‧‧Control unit

2200‧‧‧Detection feedback device

3000‧‧‧Additional devices

4000‧‧‧Massage bath equipment

5510‧‧‧Analysis unit

Claims (80)

A massage bath maintenance system, suitable for a massage bath device, comprising: at least one additional device for actuating a massage bath device; at least one slave device having a control unit for at least one of the at least one additional device Actuating, generating and transmitting at least one actuation message; a master device for controlling the at least one slave device to receive the at least one actuation message, and the master device comprises a work log aggregation unit Recording the at least one action message sent by the at least one slave device in a work log table; and an analyzing unit, configured to analyze the at least one action message in the work log table to determine the at least one add-on device Whether the action has an abnormal state. The massage bath maintenance system of claim 1, wherein the at least one slave device is a massage bath control unit and/or the analysis unit is disposed in the master device. The massage bath maintenance system of claim 1, wherein the at least one additional device is disposed in the at least one slave device. The massage bath maintenance system of claim 1, wherein the main control device further comprises a memory unit for storing the work log table, wherein the work log table is further configured to store the main control device and the at least one slave controller Communication records between devices. The massage bath maintenance system of claim 1, wherein the analyzing unit queries a built-in table according to the at least one actuation message to determine whether there is an abnormal state and/or an aging state. For example, in the massage bath maintenance system of claim 5, wherein the actuation message is an abnormal code or a physical value or a chemical value. For example, in the massage bath maintenance system of claim 6, wherein the physical value is a voltage value or a current value. The massage bath maintenance system of claim 1, wherein the at least one slave device The control unit generates and transmits the at least one actuation message to the master device or other slave device according to at least one predetermined self-detection operation procedure. The massage bath maintenance system of claim 1, wherein the master device generates at least one control message to the at least one slave device to command the control unit of the at least one slave device to generate and transmit the at least one actuation message. For example, in the massage bath maintenance system of claim 1, wherein the main control device generates a notification message according to the judgment result of the at least one actuation message. The massage bath maintenance system of claim 10, further comprising an operation panel unit electrically connected to the main control device and having a display screen for displaying the notification message. The massage bath maintenance system of claim 1, further comprising at least one wireless communication transceiver connected to the main control device and the at least one slave device to perform remote debugging maintenance. The massage bath maintenance system of claim 1 further includes a wireless communication transceiver and a cloud server, wherein the cloud server includes at least one cloud database, an authentication management component, a device management component, and an instant messaging management component. And the remote detection maintenance management component, the remote detection maintenance management component includes the analysis unit, the at least one cloud database is configured to store a corresponding serial number of the massage bath device, and the at least one wireless communication transceiver is connected to the cloud The server further transmits the work log table to the at least one cloud database of the cloud server for storage via the master device. The massage bath maintenance system of claim 13 , wherein the cloud server issues a command to the master device to collect the at least one actuation message from the at least one slave device and record the work log table, and the The work log table is stored in the main control device and/or returned to the at least one cloud database of the cloud server via the main control device for storage for maintenance. For example, the massage bath maintenance system of claim 13 of the patent scope, wherein the cloud server is The analyzing unit determines the at least one actuation message in the work log table, so that the remote detection maintenance management component executes at least one predetermined remote detection maintenance management program. The massage bath maintenance system of claim 15 , wherein the master device generates the at least one control message to the at least one slave device according to the at least one predetermined remote detection maintenance management program to command the at least one The control unit of the slave device performs warm booting and detection, and the at least one slave device generates the at least one actuation message including the detection result. The massage bath maintenance system of claim 15 , wherein the master device performs at least one maintenance operation on the at least one slave device according to the at least one predetermined remote detection maintenance management program, and executes the at least one After the maintenance operation, the control unit of the at least one slave device is instructed to perform the detection, and the at least one slave device generates the at least one actuation message including the detection result, wherein the at least one maintenance operation includes incorrectly setting the correction, and cold booting , a combination of at least one or more of the source code refill and the program version update. The utility model relates to a massage bath maintenance system, which is suitable for a massage bathing device, comprising: at least one additional device for actuating a massage bathing device; at least one slave control device, comprising a detecting feedback device and a control unit, the control unit Generating and transmitting at least one actuation message according to at least one actuation state of the at least one additional device; a master control device controlling the at least one slave control device by a master-slave connection, and the master control device includes a work log gathering unit The at least one action message is recorded in a work log table; and an analyzing unit is configured to analyze the at least one action message in the work log table to determine whether the at least one additional device has an abnormal state; wherein the control unit Controlling the detection feedback device to detect the at least one additional device and generating the at least one actuation message including the detection result for transmission to the main control device. The massage bath maintenance system of claim 18, wherein the at least one slave control device is a massage bath control unit. The massage bath maintenance system of claim 19, wherein the at least one additional device comprises one or plural of a blower, a motor, an air valve, a sensor, a pump, an ozone generator, a light control device, and a heater. combination. The massage bath maintenance system of claim 18, wherein the master device requests the at least one slave device to transmit the at least one actuation message. The massage bath maintenance system of claim 18, wherein the at least one additional device is disposed in the at least one slave device. The massage bath maintenance system of claim 18, further comprising a wireless communication transceiver and a cloud server, the cloud server comprising at least one cloud database, an authentication management component, a device management component, and an instant messaging management component And the remote detection maintenance management component, the remote detection maintenance management component includes the analysis unit, the at least one cloud database is configured to store a corresponding serial number of the massage bath device, and the at least one wireless communication transceiver is connected to the The cloud server further transmits the work log table from the master device to the cloud database of the cloud server for storage. The massage bath maintenance system of claim 23, wherein the remote detection maintenance management component of the cloud server issues a command to the main control device to request the at least one slave device to transmit the at least one actuation message. The massage bath maintenance system of claim 23, wherein the cloud server performs at least one of the remote detection maintenance management component according to the determination result of the at least one actuation message in the work log table by the analysis unit. Scheduled remote detection maintenance management program. The massage bath maintenance system of claim 25, wherein the master device generates the at least one control message according to the at least one predetermined remote detection maintenance management program to the at least one The slave device controls the control unit of the at least one slave device to perform warm booting and detecting, and the at least one slave device generates the at least one actuation message including the detection result. The massage bath maintenance system of claim 25, wherein the master device performs at least one maintenance operation on the at least one slave device according to the at least one predetermined remote detection maintenance management program, and executes the at least one After the maintenance operation, the control unit of the at least one slave device is instructed to perform the detection, and the at least one slave device generates the at least one actuation message including the detection result, wherein the at least one maintenance operation includes incorrectly setting the correction, and cold booting A combination of at least one or more of the source code refill and the program version update. The massage bath maintenance system of claim 27, wherein the main control device performs the at least one of the maintenance operations on the control unit via a maintenance interface. The massage bath maintenance system of claim 28, wherein the maintenance interface may be one or both of JTAG or RESET. The massage bath maintenance system of claim 18, wherein the detection feedback device comprises at least one switch unit and at least one sensing unit, the at least one switch unit being controlled by the control unit to turn on or off a supply of the at least one a power supply of the additional device, the at least one sensing unit is configured to detect a specific physical value between the at least one switching unit and the at least one additional device, and transmit the measured specific physical value to the control unit, by the control The unit uses the measured specific physical value as the detection result to generate the at least one actuation message and provides the at least one actuation message to the main control device. The massage bath maintenance system of claim 18, wherein the detection feedback device comprises at least one switch unit and at least one sensing unit, the at least one switch unit being controlled by the control unit to turn on or off a supply of the at least one An additional device for detecting a specific physical value of the at least one additional device and transmitting the measured specific physical value to the control unit, wherein the control unit is based on the measured specific physical value As the above detection junction And generating the at least one actuation message and providing the at least one actuation message to the master device. The massage bath maintenance system of claim 18, wherein the detection feedback device comprises at least one switch unit and at least one sensing unit, the at least one switch unit being controlled by the control unit to turn on or off a supply of the at least one An additional device for detecting a specific physical value between the power supply of the at least one additional device and the at least one additional device, and transmitting the measured specific physical value to the control unit And determining, by the control unit, the specific physical value as the detection result to generate the at least one actuation message and providing the at least one actuation message to the main control device. The massage bath maintenance system according to any one of claims 30, 31 and 32, wherein the at least one switch unit is a relay, and the physical value is a current value or a voltage judgment logic value. The massage bath maintenance system of claim 18, wherein the detection feedback device further comprises a temperature measurement deviation confirmation device electrically connected to the control unit for detecting a temperature state of a thermometer to make the detection result, The control unit generates and transmits the at least one actuation state to the main control device according to the detection result. The massage bath maintenance system of claim 34, wherein the temperature measurement deviation confirmation device has a temperature sensor and a voltage verification unit, and uses the temperature sensor and the data measured by the voltage verification unit to determine whether the temperature sensor is abnormal. The massage bath maintenance system of claim 18, wherein the analyzing unit queries a built-in table according to the at least one actuation message to determine whether there is an abnormal state and/or an aging state. The invention relates to a massage bath maintenance method, which is suitable for a massage bathing device. The method comprises the following steps: at least one slave control device generates at least one actuation message according to the action of at least one additional device corresponding to the massage bathing device and stores the at least one actuation message in a The at least one work log table built in the main control device, wherein the master control device is connected to the at least one slave control device by the master and the slave; Querying, by the work log table stored by the master device, the at least one action message of the at least one additional device; analyzing, by an analyzing unit, the at least one action message of the at least one additional device in the work log table, confirming the at least Whether an additional device has an abnormal or aging state to issue a notification message; and whether the abnormal state is excluded by the master device. The massage bath maintenance method of claim 37, further comprising: obtaining the serial number of the massage bath device from at least one cloud database of a cloud server; the cloud server confirms that the serial number is valid; and passing at least one wireless communication The transceiver device establishes a network connection between the cloud server and the master device. The massage bath maintenance method of claim 37, further comprising: establishing a master-slave connection between the at least one slave device and the master device. The massage bath maintenance method of claim 38, wherein when the cloud server confirms that the serial number is invalid or when the network connection between the cloud server and the main control device cannot be established, the following steps are further included. : The notification message is sent by the cloud server to notify the person to attend the repair; and the method ends. The massage bath maintenance method of claim 38, further comprising the following steps: when the network connection between the cloud server and the main control device is connected, the cloud server queries the work log through the main control device. The at least one activation message of the at least one additional device in the table; and determining, by the analysis unit located in the cloud server, whether the at least one additional device has an abnormal state according to the at least one actuation message, wherein when the at least one additional device is confirmed Occurrence In the normal state, the cloud server performs a predetermined remote detection maintenance management program on the at least one slave device. The massage bath maintenance method of claim 41, wherein the predetermined remote detection maintenance management program further comprises the following steps: determining whether the at least one slave device is set incorrectly, wherein when determining the at least one slave device When the setting is incorrect, correcting the setting of the at least one slave device according to the setting of the cloud server; generating and returning a corrected setting action message to the cloud server; confirming whether the at least one slave device is in normal operation; There are no other faults; and the method ends. For example, in the massage bath maintenance method of claim 42, when the at least one slave device is not in normal operation, the method further includes the following steps: the notification message is sent by the cloud server to notify the person to perform the repair; and the method is ended. For example, in the massage bath maintenance method of claim 43, when it is determined that the at least one slave device is in normal operation or when other faults are confirmed, the method further includes the following steps: confirming whether there is abnormality in the peripheral communication; controlling the at least one slave device Performing a warm power reset; generating the at least one actuation message; confirming whether the at least one slave device is functioning properly; and confirming that there are no other faults. For example, in the massage bath maintenance method of claim 44, when it is confirmed that the at least one slave device is not in normal operation, the method further includes the following steps: controlling the at least one slave device to perform a cold boot reset; Generating the at least one actuation message; confirming that the at least one slave device is functioning properly; and confirming that there are no other faults. For example, in the massage bath maintenance method of claim 44 or 45, when it is confirmed that there is another fault or the peripheral communication is normal, the method further includes the steps of: reinstalling to the at least one slave device with the existing program version; and confirming the at least Whether the slave device is working properly. The massage bath maintenance method of claim 46, when the at least one slave device is not operating normally, further comprising the steps of: confirming whether the program version of the at least one slave device is too old; if yes, updating the at least a program version of the slave device; generating the at least one action message recorded in the work log table; and confirming whether the at least one slave device is operating normally. For example, in the massage bath maintenance method of claim 47, when it is confirmed that the program version of the at least one slave device is new or the at least one slave device is not working normally, the method further includes the following steps: sending through the cloud server The notification message informs the person to attend the repair; and ends the method. A self-detection method for a massage bath maintenance system, the massage bath maintenance system comprising an operation panel unit, a main control device, at least one additional device, an analysis unit and a massage bath control unit, the operation panel unit is electrically connected The main control device has a display screen for displaying the state of the at least one additional device for actuating a massage bath device, the main control device is electrically connected to the massage bath control unit and includes a work log collecting unit, the massage bath The control unit is electrically connected to the at least one additional device and includes a detection feedback device and a control a unit, wherein the detection feedback device is configured to detect the at least one additional device, and the control unit is configured to control the detection feedback device and generate and transmit at least one actuation message to the main control device according to the detection result, so that the main The work log collecting unit of the control device records the at least one action message in a work log table, and the analyzing unit analyzes the at least one action message to determine whether the at least one additional device operates abnormally and/or ages, The at least one detection feedback device includes at least one switch unit and at least one sensing unit, the at least one switch unit includes a first switch unit, a second switch unit, and a third switch unit, and the method includes: the control unit performs the At least one of the at least one switch unit conducts a test flow; the control unit performs at least one aging and fault test flow of the at least one additional device; the control unit performs at least one non-conduction test flow of the at least one switch unit; and the method ends . The self-detection method of claim 49, wherein the at least one continuity test procedure of the at least one switch unit further comprises: not turning on the first switch unit, the second switch unit, and the third switch unit; Or not sequentially turning on the first switch unit, the second switch unit, and the third switch unit; and confirming whether at least one of the first switch unit, the second switch unit, and the third switch unit is normal Turned on; and recorded in the work log table and/or displayed on the display screen. The self-detection method of claim 49, wherein the at least one aging and fault testing process of the at least one additional device comprises: the analyzing unit calculating an aging of current and time of the at least one additional device according to the working log table a slope; the analyzing unit determines, according to the aging slope, whether the at least one additional device needs to be replaced; The analysis unit determines whether the current of the at least one additional device is less than a predetermined current. The self-detection method of claim 49, wherein the at least one non-conduction test procedure of the at least one switch unit comprises: turning on the first switch unit, the second switch unit, and the third switch unit; The first switch unit, the second switch unit, and the third switch unit are not turned on in sequence; and it is confirmed whether at least one of the first switch unit, the second switch unit, and the third switch unit is normal. Turned on; and recorded in the work log table and/or displayed on the display screen. For example, in the self-detection method of claim 52, when it is confirmed that the combination of one or more of the first switch unit, the second switch unit, and the third switch unit is not normally non-conductive, the method further includes the following steps: Generating the at least one actuation message to be recorded in the work log table and/or displayed on the display screen; and the method ends. The self-detection method of claim 51, when the analyzing unit determines that the at least one additional device needs to be replaced according to the aging slope, further comprising the steps of: generating the at least one actuation message recorded in the work log table and/or Displayed on the display screen; and the method ends. The self-detection method of claim 51, when the analyzing unit confirms that the current of the at least one additional device is greater than or equal to the predetermined current, further comprising the steps of: generating the at least one actuation message recorded in the work log table and / or displayed in the display; the method ends. For example, in the self-detection method of claim 50, when it is confirmed that the combination of one or more of the first switch unit, the second switch unit, and the third switch unit is not normally turned on, the method further includes the following steps: generating The at least one actuation message is recorded in the work log table and/or displayed on the display screen; and the method ends. A self-detecting method according to claim 49, wherein the at least one additional device comprises a heater. The self-detection method of claim 49, wherein the at least one switching unit is a relay, and the at least one sensing unit is a current sensing unit and/or a photocoupler. A self-detection method for a massage bath maintenance system, the massage bath maintenance system comprising an operation panel unit, a main control device, at least one additional device, an analysis unit and a massage bath control unit, the operation panel unit is electrically connected The main control device has a display screen for displaying the state of the at least one additional device for actuating a massage bath device, the main control device is electrically connected to the massage bath control unit and includes a work log collecting unit, the massage bath The control unit is electrically connected to the at least one additional device and includes a detection feedback device and a control unit, wherein the detection feedback device is configured to detect the at least one additional device, and the control unit is configured to control the detection feedback device and And generating, according to the detection result, at least one actuation message to the main control device, so that the work log collecting unit of the main control device records the at least one actuation message in a work log table, and the analyzing unit analyzes the at least Actuating a message to determine whether the at least one additional device is malfunctioning and/or aging, each The at least one detecting and feeding device comprises at least one switching unit and at least one sensing unit, the at least one switching unit comprises a first switching unit and a second switching unit, the method comprising: the control unit executing the at least one switching unit At least one continuity test procedure; The control unit performs at least one aging and fault testing process of the at least one additional device; the control unit performs at least one non-conducting test flow of the at least one switching unit; and the method ends. The self-detection method of claim 59, wherein the at least one continuity test procedure of the at least one switch unit further comprises: not turning on the first switch unit and the second switch unit; and sequentially or sequentially a switch unit and the second switch unit; confirming whether at least one of the first switch unit and the second switch unit is normally turned on; and recording in the work log table and/or displayed on the display screen. The self-detection method of claim 59, wherein the at least one aging and fault testing process of the at least one additional device comprises: the analyzing unit calculating an aging of current and time of the at least one additional device according to the working log table a slope; the analyzing unit determines whether the at least one additional device needs to be replaced according to the aging slope; and the analyzing unit determines whether the current of the at least one additional device is less than a predetermined current. The self-detection method of claim 59, wherein the at least one non-conduction test procedure of the at least one switch unit further comprises: turning on the first switch unit and the second switch unit; and not turning on the sequence sequentially or not sequentially Determining, by the first switch unit and the second switch unit, whether at least one of the first switch unit and the second switch unit is normally non-conductive; and recording in the work log table and/or displaying on the display screen . For example, the self-test method of claim 62, when confirming the first switch unit and the first When the combination of one or more of the two switch units is not normally non-conducting, the method further includes the steps of: generating the at least one actuation message recorded in the work log table and/or displayed on the display screen; and the method ends. The self-detection method of claim 61, when the analyzing unit determines that the at least one additional device needs to be replaced according to the aging slope, further comprising the steps of: generating the at least one actuation message recorded in the work log table and/or Displayed on the display screen; and the method ends. The self-detection method of claim 61, when the analyzing unit confirms that the current of the at least one additional device is greater than or equal to the predetermined current, further comprising the steps of: generating the at least one actuation message recorded in the work log table and / or displayed in the display; the method ends. The self-detection method of claim 61, wherein when the current of the at least one additional device has a combination of one or more of a high frequency change, an instantaneous pulse, and a low frequency change, the method further comprises the steps of: generating The at least one actuation message is recorded in the work log table and/or displayed on the display screen; and the method ends. For example, in the self-detection method of claim 60, when it is confirmed that one or both of the first switch unit and the second switch unit are not normally turned on, the method further includes the step of: generating the at least one action message recorded in the work a log table and/or displayed on the display screen; The method ends. The self-detection method of claim 59, wherein the at least one additional device comprises one or a combination of a blower, a motor, an air valve, a sensor, a pump, a heater, an ozone generator, and a light control device. . The self-detection method of claim 59, wherein the at least one switching unit is a relay, and the at least one sensing unit is a current sensing unit and/or a photocoupler. A self-detection method for a massage bath maintenance system, the massage bath maintenance system comprising an operation panel unit, a main control device, at least one additional device, an analysis unit and a massage bath control unit, the operation panel unit is electrically connected The main control device has a display screen for displaying the state of the at least one additional device for actuating a massage bath device, the main control device is electrically connected to the massage bath control unit and includes a work log collecting unit, the massage bath The control unit is electrically connected to the at least one additional device and includes a detection feedback device and a control unit, wherein the detection feedback device is configured to detect the at least one additional device, and the control unit is configured to control the detection feedback device and And generating, according to the detection result, at least one actuation message to the main control device, so that the work log collecting unit of the main control device records the at least one actuation message in a work log table, and the analyzing unit analyzes the at least Actuating a message to determine whether the at least one additional device is malfunctioning and/or aging, each The at least one detection feedback device includes at least one switch unit and at least one sensing unit, the method comprising: the control unit performing at least one continuity test procedure of the at least one switch unit; the control unit executing the at least one additional device At least one aging and fault testing process; the control unit performs at least one non-conducting test flow of the at least one switching unit; the method ends. The self-test method of claim 70, wherein the at least one continuity test procedure of the at least one switch unit further comprises the following steps: Not turning on the at least one switch unit; turning on the at least one switch unit; confirming whether the at least one switch unit can be normally turned on; and recording in the work log table and/or displayed on the display screen. The self-detection method of claim 70, wherein the at least one aging and failure test procedure of the at least one additional device further comprises the step of: calculating, by the analysis unit, current and time of the at least one additional device according to the work log table An aging slope; the analyzing unit determines whether the at least one additional device needs to be replaced according to the aging slope; and the analyzing unit determines whether the current of the at least one additional device is less than a predetermined current. The self-detection method of claim 70, wherein the at least one non-conduction test procedure of the at least one switch unit further comprises the steps of: turning on the at least one switch unit; not turning on the at least one switch unit; confirming the at least one Whether the switch unit can be normally not turned on; and recorded in the work log table and/or displayed on the display screen. The self-detection method of claim 71, wherein when it is confirmed that the at least one switch unit is not normally turned on, the method further includes the step of: generating the at least one action message recorded in the work log table and/or displayed on the display screen ; and the method ends. The self-detection method of claim 72, wherein when the analyzing unit determines that the at least one additional device needs to be replaced according to the aging slope, the method further includes the step of: generating the at least one actuation message recorded in the work log table and/or Or displayed on the display screen; And the method ends. The self-detection method of claim 72, wherein when the analyzing unit confirms that the current of the at least one additional device is greater than or equal to the predetermined current, further comprising the step of: generating the at least one actuation message recorded in the work log table And/or displayed on the display screen; and the method ends. For example, in the self-detection method of claim 73, when it is confirmed that the at least one switch unit is not normally non-conductive, the method further includes the following steps: generating the at least one action message recorded in the work log table and/or displayed on the display screen ; and the method ends. The self-detection method of claim 72, wherein when the current of the at least one additional device has a combination of one or more of a high frequency change, an instantaneous pulse, and a low frequency change, the method further comprises the steps of: generating The at least one actuation message is recorded in the work log table and/or displayed on the display screen; and the method ends. The self-detection method of claim 70, wherein the at least one additional device comprises one or a combination of a blower, a motor, an air valve, a sensor, a pump, a heater, an ozone generator, and a light control device. . The self-detection method of claim 70, wherein the at least one switching unit is a relay, and the at least one sensing unit is a current sensing unit and/or a photocoupler.