TWI559129B - Reciprocal detecting method, reciprocal detecting device and power management system - Google Patents

Description

Interactive detection method, interaction detection device and power management system

The invention relates to an environment control technology, and in particular to an interaction detection method, an interaction detection device and a power management system.

With the global population booming, the energy crisis has been a topic of great concern to countries in recent years. The catastrophe of energy will not only cause human inconvenience in life, but also highly affect global economic activities, and even trigger the exploitation of resources by various countries and further trigger war.

In this regard, energy conservation is still one of the most effective means of solving the energy crisis. However, people still want to live in a comfortable and convenient environment, so that a large number of electronic products have been applied in daily life. Therefore, how to balance energy conservation and maintain the convenience and comfort of life is still a dilemma.

Here, if you want to save energy and maintain the convenience and comfort of life, you must be able to effectively control the operation of the surrounding electronic products. However, monitoring the large number of electronic products around by traditional manual methods is not effective, and lacks the immediacy of monitoring. Among them, there are layers of influence and interaction between various types of electronic products. In the case of the failure, it is not a simple task.

In addition, if you fail to find out the electronic products that operate abnormally, and the energy consumption is also a major problem that worsens the energy crisis.

Moreover, the previous power-saving system rarely uses intelligent analysis of historical data for scheduling planning, resulting in possible power waste. In addition, even if a human body infrared sensor (PIR sensor) is used, the existing system cannot automatically detect it, and if the human body infrared sensor is broken, it will cause trouble to the field user. At the same time, it may cause waste of electricity.

The invention triggers the detection program by judging whether the operating state is normal, thereby performing interaction detection between the sensor and the electronic product, thereby solving the traditional monitoring of the operation state of the electronic product and the failure of the sensor. , non-conformity and lack of immediacy.

The invention provides an interaction detecting method and device, thereby finding out the reason that the operating state of the electronic product does not conform to the normal state, and performing humanized adjustment thereof, and eliminating the fault problem of the sensor, further achieving energy saving and maintaining life. Convenience and comfort.

The present invention provides an interactive detection method comprising the following steps. Determining whether the first operational state of the first device conforms to the normal state, and when the first operational state does not conform to the normal state, the detection process is performed. The test procedure includes the following steps. It is determined whether the sensor detects an inductive input during the first time period. When the sensor detects an inductive input during the first time period, the first operational state is maintained. Feeling When the sensor does not detect the sensing input during the first time period, the scheduling control program is started to change the first device from the first operating state to the second operating state to conform to the normal state.

In an embodiment of the invention, determining whether the first operational state is consistent A schedule control information is used to determine whether the first operational status is in accordance with historical operational information, and when the first operational status does not meet one of the schedule control information and the historical operational information, the first operational status is determined to be inconsistent with the normal standard.

In another embodiment of the present invention, the historical operational information is updated according to the first operational status.

In another embodiment of the present invention, determining whether to read the active input corresponding to the third operating state of the first device in a second time period, and discontinuing the scheduling control program and the second operating state, and in the second time period When the active input corresponding to the third operational state of the first device is read and the scheduling control program and the second operational state are suspended, the fault information of the sensor is established.

In another embodiment of the present invention, the buffer warning signal is issued within the third time period, and after the third time period, the scheduling control program is started to change the first device from the first operating state to the second operating state, In order to meet the normal standard.

In another embodiment of the invention, the detection procedure is re-executed after the fourth time period.

In another embodiment of the invention, a second device associated with the first device is activated.

The invention provides an interaction detecting device, including monitoring and statistical mode Group and management modules. The monitoring and statistics module is configured to determine whether the first operational state of the first device conforms to a normal state. The management module is coupled to the monitoring and statistics module, and when the first operating state does not meet the normal standard, the detecting process is executed, and in the detecting program, determining whether the sensor detects the sensing input in the first time period When the sensor detects the sensing input in the first time period, the first operating state is maintained, and when the sensor does not detect the sensing input in the first time period, the scheduling control program is started to The first device changes from the first operational state to the second operational state to conform to the normal state.

As described above, the present invention does not match the first operational state of the first device. When the normal state standard is met, the execution of the detection program is triggered. In the detecting process, when the sensor detects the sensing input of the corresponding user in the first time period, the first operating state of the first device is maintained, thereby providing a suitable working environment for the user. When the sensor does not detect the sensing input during the first time period, the scheduling control program is started to change the first device from the first operating state to the second operating state to conform to the normal standard, thereby saving energy.

The above description of the present invention and the following description of the embodiments are The spirit and principle of the invention are set forth and illustrated, and further explanation of the scope of the invention is provided.

100‧‧‧Interactive detection device

110‧‧‧Monitoring and Statistics Module

120‧‧‧Management module

10‧‧‧Environment sensing device

11‧‧‧ Sensor

12‧‧‧Electric meter

13‧‧‧First wireless node device

20‧‧‧Air conditioning unit

21‧‧‧Inverter

22‧‧‧Program Logic Controller

23‧‧‧Second wireless node device

30‧‧‧ Coordinator

40‧‧‧Center host

50‧‧‧Energy Management Host

60‧‧‧ Terminal equipment

S200, S300, S310~S330‧‧‧ steps of the interactive detection method

1 is a block diagram of an interaction detecting apparatus according to an embodiment of the present invention.

2 is a system architecture of a power management system according to an embodiment of the present invention Figure.

FIG. 3 is a flow chart of an interaction detection method according to an embodiment of the present invention.

The detailed features of the present invention are described in the following description, which is sufficient for any skilled person to understand the technical contents of the present invention and to implement it, and according to the contents disclosed in the specification, the patent application scope and the drawings, any familiarity The related objects and advantages of the present invention will be readily understood by those skilled in the art. The following examples are intended to further illustrate the invention, but are not intended to limit the scope of the invention.

1 is a block diagram of an interaction detecting apparatus 100 in accordance with an embodiment of the present invention. As shown in FIG. 1, the interaction detecting apparatus 100 includes a monitoring and statistics module 110 and a management module 120. The management module 120 is coupled to the monitoring and statistics module 110. In the embodiment of the present invention, the interaction detecting apparatus 100 may be a desktop computer, a notebook computer, or various intelligent electronic devices, which is not limited herein. The monitoring and statistics module 110 and the management module 120 can be various functional chips or microprocessors, and are not limited herein.

In the embodiment of the present invention, the monitoring and statistics module 110 is configured to determine whether the first operational state of the first device conforms to a normal state. For example, the first device may be a lighting device, an air conditioning device, a power supply device, a communication device, and various surrounding application devices, which are not limited herein. For the convenience of description, the target of the interactive detection device 100 to perform the mutual detection is set as a conference room, and the An example of a device is set as a lighting device in a conference room. The first operational state is a state measured when the interaction detecting device 100 performs a routine interactive detection on the first device, such as a light on or off.

Normal standards can be set based on scheduling control information and historical operational information. For example, the schedule control information can correspond to the scheduled usage schedule of the conference room. For example, the conference room was reserved for use at 2 pm on Friday and was not reserved for use at 9 am on Saturday. The historical operation information may correspond to the actual operation record of the first device in the past month, but the recording time may also be three days, one week, or even six months, and is not limited herein. Therefore, when the monitoring and statistics module 110 determines whether the first operating state of the first device meets the normal state, it may further determine whether the first operating state meets the scheduling control information, and whether the first operating state meets the historical operation information. . When the monitoring and statistics module 110 determines that the first operational state does not meet one of the scheduling control information and the historical operational information, it is determined that the first operational state is not in compliance with the normal state.

Then, in the embodiment of the present invention, the management module 120 is configured to execute the detection process when the first operational state does not meet the normal standard. For example, when the management module 120 considers that the probability of the first device being turned off according to the normal state is large, but actually detecting that the first operating state of the first device is light, the user may not be registered. The first device is turned on when the schedule is reserved, but the conference room is temporarily used, or it may be turned on by other factors. Therefore, the management module 120 will execute a detection program to determine whether there is a need to continue to maintain the first device in the first operational state of the light.

In the detection process, the management module 120 can determine whether the sensor detects the sensing input during the first time period. The sensing input can be a human body infrared sensor in a conference room, a temperature sensor, an ultrasonic sensor, or a measured signal of other types of sensors, and the sensing signal can represent that a user is using meeting room. The first time period may be 5 minutes, or may be other time intervals, which are not limited herein. When the management module 120 determines that the sensor detects the sensing input during the first time period, the first operating state is maintained. In this way, although the user does not register the conference room in the reservation use schedule, and does not use the conference room normally at this time in the past month, the interactive detection device 100 still maintains the illumination lightly (the first) An operational state) environment.

In the embodiment of the present invention, after the management module 120 determines that the sensor detects the sensing input in the first time period and maintains the first operating state, the second device related to the first device may be further activated. For example, in this stage, the interaction detecting apparatus 100 activates the related second device in addition to humanizing the environment of the light (first operating state) to facilitate the user's work. Wherein, if the first device is a lighting device, the second device may be an air conditioning device, a power supply device, a communication device, and various surrounding application devices. In the embodiment of the present invention, when the management module 120 determines that the sensor detects the sensing input in the first time period, the historical operation information is further updated according to the first operating state. In this way, the user's actual usage habits and usage requirements can be closer to the conference room. In the embodiment of the present invention, after the management module 120 determines that the sensor detects the sensing input in the first time period and maintains the first operating state, the management module 120 may further perform the detection after the fourth time period. program. In this way, the detection program is repeatedly executed to ensure that the conference room does not have an abnormal state of the first device, resulting in wasted power. The fourth time period may be 30 minutes, or may be other time intervals, which are not limited herein.

In the detecting process, when the management module 120 determines that the sensor does not detect the sensing input during the first time period, the scheduling control program is started to change the first device from the first operating state to the second operating state, In order to meet the normal standard. For example, when a user accidentally touches the switch of the first device and leaves the conference room, the sensor does not detect the sensing input within 5 minutes. Therefore, the management module 120 will consider the first at this stage. The device does not need to be maintained in the first operational state of the lighting, but is further changed to a second operational state that conforms to the normal state, such as a light off. In the embodiment of the present invention, when the management module 120 determines that the sensor does not detect the sensing input in the first time period, the third device may further move to the third time period before changing the first device to the second operating state. Within this, a buffer warning signal is issued. The buffer warning signal can be a flashing light, a broadcast, or other information, which is not limited herein. After the buffer warning signal is issued and after the third time period, the scheduling control program is started to change the first device from the first operating state to the second operating state to conform to the normal standard. The third time period may be 2 minutes or other time intervals, which is not limited herein.

In another embodiment of the present invention, after the first device is changed to the second operating state, the management module 120 may further determine whether the active input corresponding to the third operating state of the first device is read in the second time period. Suspend the schedule control program and the second operational status. The active input may be the activation signal of the switch of the first device or the adjustment signal of the first device, which is not limited herein. The first time period can be 3 minutes, it can be other time intervals, and there is no limit here. For example, when the sensor will not detect the inductive input within 5 minutes (the first time period) and switch to the lamp off (the second operating state according to the normal standard), this may be a feeling. The detector has failed. Therefore, if the user does intentionally use the conference room, the switch of the first device should be actively generated to generate the activation signal (active input), thereby suspending the scheduling control program and the second operational state (such as the light off), so that the user The first device changes to a third operational state (eg, lights up).

In the embodiment of the present invention, when the management module 120 determines to read the active input corresponding to the third operating state of the first device in the second time period and suspends the scheduling control program and the second operating state, the management module 120 may further start. A second device related to the first device. For example, the management module 120 at this stage changes the first device to light (the third operational state) in addition to the corresponding active input, and also activates the related second device (for example, simultaneously starting the air conditioner, the outlet power supply, and the automatic Start the projector, or start a wireless network device, etc.) to facilitate the user's work.

In addition, another feature of the present invention is that the sensor (for example, a PIR motion sensor) can be automatically debugged, and the fault information of the sensor is actively established to the manager/management device. For example, determining whether to read an active input in a second time period and suspending the scheduling control program, for example, the lighting/air conditioning of a conference room is currently on, but the management platform analyzes according to historical record/schedule information. It is known that the lighting/air conditioning of the conference room should be closed. Therefore, after the management platform closes the lighting/air conditioning of the conference room, it will be manually opened by the on-site personnel within 5 minutes. At this time, the management platform determines the judgment of the scheduling control program. Wrong and aborted the row The program controls the program and adds this information to the history/scheduling information to prevent accidental shutdown of the fixture/air conditioner in the same situation in the future. In addition, the management platform reads the first and second time period information of the infrared motion sensor of the conference room (for example, 10 minutes before and after closing the room lighting/air conditioning), if the infrared motion sensor displays no action sense If the measurement is recorded, the infrared motion sensor is determined to be faulty. The reason is that since the person who turned on the conference room lamp/air conditioner is turned on again after 5 minutes but does not detect the action record, the possibility of the sensor failure is equivalent. High, so the fault information of the sensor is established to the management terminal).

2 is a system architecture diagram of a power management system in accordance with an embodiment of the present invention. As shown in FIG. 2, an environment sensing device 10 includes one or more sensors 11, one or more electric meters 12, and a first wireless node device 13, and the sensor 11 senses the scene environment. After the measurement, the information is transmitted to the first wireless node device 13, the electric meter 12 transmits the power consumption information to the first wireless node device 13; and the air conditioning device 20 includes one or more frequency converters 21 and a program logic controller. 22. A second wireless node device 23; a coordinator 30, receiving information from the first wireless node device 13 and the second wireless node device 23, and controlling the first wireless node device 13 and the second wireless node The device 23 receives a message from the coordinator 30 and controls the coordinator 30; an energy management host 50 collects and analyzes information received from the central host 40, and analyzes the center host according to the analysis result. 40, the management command is issued, the central host 40 manages the environment sensing device 10 or the air conditioning device 20 through the coordinator 30; and a terminal device 60 receives the information of the central host 40 and the energy management host 50. Displayed in one On the screen. The energy management host 50 determines whether a first operational state of the environmental sensing device 10 meets a normal state; and when the first operational state does not meet the normal standard, a detection process is performed; wherein the detection process includes: Determining whether the sensor 11 detects a sensing input during a first time period; when the sensor 11 detects the sensing input during the first time period, maintaining the first operating state; When the sensor 11 does not detect the sensing input during the first time period, the energy management host 50 starts a scheduling control program, and the scheduling control program issues an instruction to the central host 40, and the central host 40 The environment sensing device 10 or the air conditioning device 20 is changed from the first operating state to a second operating state through the coordinator 30 to comply with the normal state.

FIG. 3 is a flow chart of an interaction detection method according to an embodiment of the present invention. As shown in FIG. 3, the interaction detection method in the embodiment of the present invention includes steps S200 and S300. Step S300 further includes steps S310 to S330.

In step S200, the monitoring and statistics module 110 determines whether the first operational state of the first device conforms to the normal state. In step S300, when the monitoring and statistics module 110 determines that the first operational state does not meet the normal standard, the detection procedure is executed. In step S310, the management module 120 determines whether the sensor detects an inductive input during the first time period. In step S320, when the management module 120 determines that the sensor detects the sensing input in the first time period, the first operating state is maintained. In step S330, when the management module 120 determines that the sensor does not detect the sensing input in the first time period, the scheduling control program is started to change the first device from the first operating state to the second operating state. In order to meet the normal standard. These steps have been detailed above, This will not be repeated here.

In summary, the present invention triggers the execution of the detection program when the first operational state of the first device does not meet one of the schedule control information or the historical operational information in the normal standard. In the detecting process, when the sensor detects the sensing input of the corresponding user in the first time period, maintaining the first operating state of the first device, updating the historical operation information, and starting the related second device, Thereby providing a user-friendly working environment. When the sensor does not detect the sensing input during the first time period, the buffer warning signal may be sent within the third time period, and then the scheduling control program is started to change the first device from the first operating state to the second state. Operational status, in order to meet the normal standards, to save energy. And in order to eliminate the damage factor of the sensor, after reading an active input in the second time period and aborting the scheduling control program, determining that the sensor does not detect the sensing input in the first time period and the second time period , the fault information of the sensor is established.

Although the present invention has been disclosed above in the foregoing embodiments, it is not intended to limit the invention. It is within the scope of the invention to be modified and modified without departing from the spirit and scope of the invention. Please refer to the attached patent application for the scope of protection defined by the present invention.

S200, S300, S310~S330‧‧‧ steps of the interactive detection method

Claims (15)

An interaction detecting method includes: determining whether a first operating state of a first device meets a normal state standard, the normal state standard includes a scheduling control information; and when the first operating state does not meet the row in the normal state standard When the control information is executed, a detection process is performed; wherein the detection process includes: determining whether a sensor detects an inductive input in a first time period; and detecting, when the sensor is detected in the first time period When the sensing input is performed, maintaining the first operating state; and when the sensor does not detect the sensing input during the first time period, starting a scheduling control program to the first device from the first An operational state is changed to a second operational state to conform to the normal state. The interaction detection method of claim 1, wherein the normality standard further includes a historical operation information, and in the step of determining whether the first operational state of the first device meets the normal state, the method further includes: determining the first Whether the operational status meets the historical operational information in the normal standard; When the first operating state does not meet one of the scheduling control information and the historical operation information, it is determined that the first operating state is not in conformity with the normal state. The method of claim 2, wherein when the sensor detects the sensing input during the first time period, the step of maintaining the first operating state further includes: according to the first Operation status to update the historical operation information. The interaction detection method of claim 1, wherein when the sensor does not detect the sensing input during the first time period, the scheduling control program is started to the first device from the first After the operating state is changed to the second operating state to comply with the normal state, the method further includes: determining whether to read an active input in a second time period to suspend the scheduling control program; and when the sensor is When the sensing input is not detected in the first time period and the second time period, a fault information of the sensor is established. The interaction detection method of claim 1, wherein when the sensor does not detect the sensing input during the first time period, the scheduling control program is started to the first device from the first The step of changing the operating state to the second operating state to meet the normal state criterion further comprises: issuing a buffer warning signal within a third time period; After the third time period, the scheduling control program is started to change the first device from the first operating state to the second operating state to comply with the normal state. The method of claim 1, wherein when the sensor detects the sensing input during the first time period, the step of maintaining the first operating state further comprises: After the time period, the test is re-executed. The method of claim 1, wherein when the sensor detects the sensing input during the first time period, after the step of maintaining the first operating state, the method further includes: starting a second device of the first device. An interaction detecting device includes: a monitoring and counting module, configured to determine whether a first operating state of a first device meets a normal state standard, the normal state standard includes a scheduling control information; and a management module coupled And the monitoring and counting module is configured to: when the first operating state does not meet the scheduling control information in the normal state, perform a detecting process, and in the detecting process, determine a sensor Whether a sensing input is detected during a first time period, and when the sensor detects the sensing input during the first time period, maintaining the first operating state, and when the sensor is at the first When the sensor input is not detected during the time period, A scheduling control program is initiated to change the first device from the first operational state to a second operational state to conform to the normal state. The interaction detection device of claim 8, wherein the normality standard further includes a historical operation information, and the monitoring and statistics module further determines whether the first operational state meets the historical operational information in the normal standard, and When the first operating state does not meet one of the scheduling control information and the historical operation information, it is determined that the first operating state is not in conformity with the normal state. The interaction detecting device of claim 8, wherein when the management module determines that the sensor detects the sensing input during the first time period, the historical operation is further updated according to the first operating state. News. The interaction detecting device of claim 8, wherein the management module starts the scheduling control program to change the first device from the first operating state to the second operating state to conform to the normal state. Further determining whether to read an active input during a second time period to suspend the scheduling control program, and when the sensor does not detect the sensing input during the first time period and the second time period, Establish a fault information for the sensor. The interaction detecting device of claim 8, wherein when the management module determines that the sensor does not detect the sensing input during the first time period, further sends a message within a third time period. Buffering the warning signal, and after the third time period, starting the scheduling control program to remove the first device from the The first operational state changes to the second operational state to conform to the normal state. The interaction detecting device of claim 8, wherein the management module determines that the sensor detects the sensing input in the first time period to maintain the first operating state, and further in a fourth time period. After that, the test is re-executed. The interaction detecting device of claim 8, wherein the management module further activates the first operation state after determining that the sensor detects the sensing input in the first time period to maintain the first operating state A second device of a device. A power management system is applicable to an energy management host, the energy management host is configured to perform the interaction detection method as claimed in claim 1, the power management system includes: an environment sensing device, including one or more sensing The device, the one or more electric meters, and a first wireless node device, the sensor senses the field environment and transmits the information to the first wireless node device, the meter transmits the power information to the first wireless device a node device; an air conditioning device comprising one or more frequency converters, a program logic controller, and a second wireless node device; a coordinator receiving information from the first wireless node device and the second wireless node device, And controlling the first wireless node device and the second wireless node device; a central host receiving information from the coordinator and controlling the coordinator; and a terminal device receiving information of the central host and the energy management host and displaying the information on a screen; the energy management host receiving the host from the center And determining whether a first operational state of the environmental sensing device meets one of the schedule control information in a normal state, and when the first operational state does not meet the scheduling control information in the normal state, Performing a detection process, wherein the detecting process includes: determining whether the sensor of the environment sensing device detects an inductive input during a first time period; and detecting the sensor during the first time period When the input is sensed, the first operational state is maintained; and when the sensor does not detect the sensing input during the first time period, the energy management host initiates a scheduling control program, the scheduling control program Sending an instruction to the central host, the central host, through the coordinator, changing the environmental sensing device or the air conditioning device from the first operating state to a second operational state To meet the normal standards.