DE112020007166T5 - CONTROL SYSTEM AND ELECTRONIC EQUIPMENT FOR AN INTELLIGENT WORK SITE - Google Patents

Abstract

The present invention provides a control system (100) and an electronic device (10) for an intelligent construction site. The electronic device (10) has an operating mode and a non-operating mode, the electronic device (10) comprising a sensor control module (11) and a communication module (12), wherein when the electronic device (10) is in the non-operating mode and a communication connection is established between the sensor control module (11) and the input sensor of the intelligent construction site, the sensor control module (11) controls the electronic device (10) to switch from the non-operating mode to the operating mode, and when the electronic device ( 10) is in the operating mode and a communication link is established between the sensor control module and the output sensor of the intelligent construction site, the sensor control module (11) controls the electronic device (10) to switch from the operating mode to the non-operating mode.

Description

TECHNICAL AREA

The present invention generally relates to the control technology for an intelligent construction site. More specifically, the present invention relates to an electronic device for an intelligent construction site and a control system for an intelligent construction site.

STATE OF THE ART

With the development of the Internet of Things for industry, intelligent electronic devices with Internet of Things (loT) functionality have found wider and wider application in intelligent construction sites. In order for the functions such as positioning, real-time tracking, status monitoring, etc. to be used by the electronic equipment's companion in the intelligent construction site, the electronic equipment usually needs to be equipped with various types of sensors and electronic parts. In the electronic equipment, when power is required to be supplied to numerous electronic parts, there are the problems of rapid power consumption of the battery and frequent charging of the electronic equipment. When a large number of electronic devices are operated on the intelligent construction site, in order to meet the charging needs of these electronic devices, it is necessary to provide sufficient charging facilities on or near the intelligent construction site. There is therefore a need to provide a technical concept for solving the problems mentioned according to the current state of the art.

OBJECT OF THE INVENTION

In view of the above problems of the prior art, according to embodiments according to a first aspect of the present invention, there is provided an electronic device for an intelligent construction site, the electronic device having an operating mode and a non-operating mode, the electronic device having a sensor control module and a Communication module includes, wherein when the electronic device is in the non-operational mode and a communication link is established between the sensor control module and the input sensor of the intelligent construction site, the sensor control module controls the electronic device to switch from the non-operational mode to the operational mode, and when the electronic device is in the operating mode and a communication link is established between the sensor control module and the output sensor of the intelligent construction site, the sensor control module controls the electronic device to switch from the operating mode to the non-operating mode.

• die mit der intelligenten Baustelle verbundene elektronische Einrichtung, eine Identitätsbestätigungseinrichtung, die eine Eingangs-Identitätsbestätigungseinrichtung und eine Ausgangs-Identitätsbestätigungseinrichtung umfasst, und einen Server, welcher jeweils eine Kommunikationsverbindung mit der elektronischen Einrichtung und der Identitätsbestätigungseinrichtung aufweist, wobei bei Bestätigung des Mitführers der elektronischen Einrichtung durch die Eingangs-Identitätsbestätigungseinrichtung die Eingangs-Identitätsbestätigungseinrichtung dem Mitführer das Passieren des Eingangs der intelligenten Baustelle gestattet und bei Bestätigung des Mitführers der elektronischen Einrichtung durch die Ausgangs-Identitätsbestätigungseinrichtung das Ausgangs- Identitätsbestätigungseinrichtung dem Mitführer das Passieren des Ausgangs der intelligenten Baustelle gestattet, und der Server dazu ausgebildet ist, beim Empfangen einer von der elektronischen Einrichtung stammenden Gerätekennung und einer von der Eingangs-Identitätsbestätigungseinrichtung stammenden Identitätskennung einen Aktivierungsbefehl zur Aktivierung der elektronischen Einrichtung an die elektronische Einrichtung zu senden, wobei der Server beim Empfangen einer von der elektronischen Einrichtung stammenden Gerätekennung und einer von der Ausgangs-Identitätsbestätigungseinrichtung stammenden Identitätskennung einen Deaktivierungsbefehl zur Deaktivierung der elektronischen Einrichtung an die elektronische Einrichtung sendet.

According to an embodiment according to a second aspect of the present invention, there is provided a control system for a smart construction site, comprising:

• the electronic device connected to the intelligent construction site, an identity confirmation device, which comprises an input identity confirmation device and an output identity confirmation device, and a server, which respectively has a communication connection with the electronic device and the identity confirmation device, wherein when confirming the carrier of the electronic device by the entry identity confirmation device the entry identity confirmation device allows the passenger to pass through the entrance of the intelligent construction site and upon confirmation of the companion of the electronic device by the exit identity confirmation device the exit identity confirmation device allows the passenger to pass through the exit of the intelligent construction site, and the server to do so is designed, upon receipt of a device identifier originating from the electronic device and an identity identifier originating from the incoming identity confirmation device, to send an activation command for activating the electronic device to the electronic device, wherein the server upon receiving a device identifier originating from the electronic device and one from the identity identifier originating from the initial identity confirmation device sends a deactivation command for deactivating the electronic device to the electronic device.

It can be seen that according to embodiments of the present invention the control of the automatic switching of the electronic device between operating mode and non-operating mode is realized. This ensures that the electronic device is in the operating mode when it is required to operate and perform its intelligent functions, while when it is not required to be operated, the electronic device is in the sleep mode and consumes extremely little battery power. Thus, unnecessary power consumption is saved, greatly extending the battery life of the electronic device.

According to a further embodiment of the present invention, switching is also carried out when it is detected that the device identifier does not match the identity identifier of the person carrying the electronic device, with the irregular incident being marked at the same time with the mismatch of the two identifiers for the purpose of tracking.

character list

• 1 Fig. 12 shows schematically the control system for an intelligent construction site according to a possible embodiment of the present invention.
• 2 Figure 12 shows the operating environment with possible realization of some embodiments of the present invention.
• 3 shows the control flow of a possible embodiment of the present invention for an intelligent construction site.

SPECIFIC EMBODIMENTS

A detailed description of embodiments of the present invention is given below with reference to the attached figures.

1 FIG. 12 schematically shows the control system 100 for an intelligent construction site according to a possible embodiment of the present invention. 2 Figure 12 shows the operating environment with possible realization of some embodiments of the present invention. It is understood that the present invention is not limited to 2 scheme shown is limited.

As in 1 and 2 shown, the control system 100 mainly comprises the sensor 11', the electronic device 10, the identity confirmation device 20 and the server 30.

The electronic device 10 is connected to the intelligent construction site, using the detection and communication function of the electronic device to determine the position, tracking, authorization, alerting and organization of the work progress for people located on the intelligent construction site, with a measurement of utilization rate, air quality, etc. of the intelligent construction site is possible.

The electronic device 10 can be built into one of the devices connected to the intelligent construction site. These devices include, for example, protective helmets and worker's name tags or power tools.

The electronic device 10 mainly includes the sensor control module 11 and the communication module 12, and in addition to the sensor control module 11 and the communication module 12 installed in the electronic device 10, the electronic module 14 and the battery 13.

The battery 13 is the power source for the electronic device 10. This means that the battery 13 supplies the sensor control module 11, the communication module 12 and the additional electronic module 14 in the electronic device 10 with power. The battery 13 can be a dry battery or a rechargeable battery. In one embodiment, the battery 13 comprises two rechargeable batteries or dry batteries coupled together.

The additional electronic module 14 may include sensors (e.g., the sensors may include different types of sensors such as inertial sensors or photosensitive sensors), positioning devices (e.g., GPS positioning devices), audible-optical alarm devices, and so on. It goes without saying that the additional electronic module 14 can be designed in accordance with the specific requirements, without the present invention imposing a restriction in this regard.

The sensor control module 11 can include a control device and a sensor unit in which the device identifier ID_1 of the electronic device 10 is stored. The device identifier can uniquely identify the electronic device 10 . Thus, various devices provided with the electronic device 10, such as safety helmets, name tags of the construction site, can be unmistakably identified by the device identifier. The device identifier can include digital codes that are written into the sensor unit. The device identifier may also include basic information about the worker who corresponds to the electronic device 10 (e.g., basic information about the worker who is assigned the hard hat with the electronic device 10) and/or basic information about the electronic device 10.

In one embodiment, the sensor unit is embodied as a near field communication (NFC) sensor unit (for example as an NFC chip).

That is, in the embodiment, the sensor control module 11 includes a near field communication (NFC) sensor unit and a controller. In the embodiment, the sensor 11' installed as an entrance NFC scanning device at the entrance of the intelligent construction site and as an exit NFC scanning device at the exit of the intelligent construction site.

In a further embodiment, the sensor unit is designed as a Bluetooth sensor unit, which means that in the relevant embodiment the sensor control module 11 comprises a Bluetooth sensor unit (for example BLE unit) and a control unit. In the embodiment, the sensor 11′ is in the form of a Bluetooth beacon, the Bluetooth beacon being, for example, a specific Bluetooth beacon labeled “activation and deactivation”.

The communication module 12 can be embodied as a far-field communication module, for example as a high-range radio communication module (long range radio), hereinafter referred to as the Lora communication module for short. In one embodiment, the Lora communication module of the electronic device 10 exchanges information with the server 30 via the Lora gate G.

The electronic device 10 has an operational mode and a non-operational mode. In the operating mode, the electronic device 10 is in the regular operating state, with the battery 13 having a relatively high power consumption. In the non-operational mode, most or all of the electronic parts of the electronic device 10 are in the sleep mode, with the battery 13 having an extremely low power consumption.

It goes without saying that the operating mode is understood to mean the state with operation (activation) of all electronic parts of the electronic device (for example sensor control module 11, communication module 12 and additional electronic module 14). Once the electronic device is activated under the control of an activation command, the operational mode is entered.

It is understood that the non-operational mode is understood to mean the state in which all or most of the electronic parts of the electronic device (e.g. electronic parts apart from the Bluetooth sensor unit) are in sleep mode. In other words, the non-operational mode can be understood as a state with zero or near zero power consumption of the device, for example shutdown mode, sleep mode or low power consumption mode. Once the electronic device is disabled under control of a disable command, the non-operational mode is entered.

The identity certifying device 20 may comprise an inbound identity certifying device and an egress identity certifying device. Persons wishing to enter the construction site will be permitted or otherwise prohibited from entering the construction site after confirmation by the entry identity verification facility. Persons wishing to leave the site will be permitted or otherwise prohibited from leaving the site after confirmation by the exit identity verification facility.

Different types of confirmation can be used for the identity confirmation device 20, for example face recognition, iris recognition, fingerprint recognition, or voiceprint recognition. After the identity confirmation device 20 has sent an identity code ID_2 to a person who wants to enter or leave the construction site, the identity code ID_2 is transmitted to the server 30 . The entrainment identifier can be used to identify the entrainment in question. This means that a clear identification of the person carrying it is possible. The identifier includes at least one of the following methods, for example: capturing the facial image, the iris features, the fingerprint or the voiceprint.

In one embodiment, the input identity confirmation device and the output identity confirmation device each comprise a face recognition unit 21, a processor unit 22 and a communication unit 23. The face recognition unit 21 transmits the captured facial image to the processor unit 22. The processor unit 22 carries out the identification of the facial image and makes decisions based on it of the stored personal information, a determination as to whether the person concerned is permitted to enter the intelligent construction site or to leave the intelligent construction site. At the same time, the communication unit 23 sends the facial image ID_2 to the server 30.

The server 30 can be in the form of a remote server or cloud server. The server 30 may include a communication unit 31 and a processor unit 32 . The communication unit 32 is used to receive and send information, for example to receive the device identifier ID_1 originating from the electronic device 10 and the identity identifier ID_2 originating from the identity confirmation device 20 and to generate an INS command (at for example activation command with instructions to activate the electronic device 10, deactivation command with instructions to deactivate the electronic device 10 or intercept command to intercept people entering or leaving the construction site). The communication unit 31 then sends the command to the electronic device 10 and/or the identity confirmation device 20.

It is understood that the entrance to the intelligent construction site can comprise several entrance gates, i.e. gates for entering the intelligent construction site as well as gates for entering certain points within the construction site (e.g. the intelligent construction site in the broadest sense can comprise construction areas and habitable areas, with certain points within the Construction site may include construction areas where the electronic device in the operating mode is required to implement the intelligent functions).

Similarly, the exit of the intelligent construction site can include multiple exit gates, i.e. gates for exiting the intelligent construction site as well as gates for exiting certain places within the construction site (for example, when the workers leave the construction area and enter the occupied area, the electronic device can be deactivated to save energy).

It is understood that the intelligent construction site may include multiple entrances and exits, where the respective entrances and exits may be planned as different openings to the entrance and exit, or entrance and exit may be planned at the same opening, or entrance and exit at different openings neighboring positions can be planned. Regarding the various designs of entrances and exits of the construction site, because of the different direction of people at the entrance or exit, the entrance identity confirmation device and the exit identity confirmation device can be installed separately, with the entrance sensor and the exit sensor also installed separately could be.

It is understood that if the entrance and exit are designed as the same opening (e.g. the same lock) or adjacent openings (e.g. adjacent entrance lock and exit lock), the entrance and exit can share the same Bluetooth beacon, for example the special Bluetooth beacon mentioned. In cases where there is a relatively large distance between the input and output, the input and output can each be provided with a Bluetooth beacon, for example the special Bluetooth beacon mentioned.

It goes without saying that with regard to the multiple entrances or multiple exits or the multiple entrances and exits of the intelligent construction site for each opening, the control solution according to embodiments of the present invention is possible with appropriate devices.

The following is done using 3 the description of the control sequence 300 of a possible embodiment of the present invention using the example of a worker entering the intelligent construction site and leaving the intelligent construction site.

In box 301, when the companion of the electronic equipment 10 (for example, the worker W) carrying the electronic equipment is near the entrance or exit of the intelligent construction site and between the sensor unit of the sensor control module 11 and the entrance sensor or the exit sensor the intelligent construction site a communication connection is established, the control unit of the sensor control module 11 reads the device identifier ID_1 of the electronic device 10 from the sensor unit.

In an embodiment with the realization of the sensor unit as an NFC sensor unit (for example NFC chip) and when the worker enters the intelligent construction site, the electronic device 10 is in the non-operating mode. The worker, carrying the electronic device 10 in the non-operational mode, comes near the entrance of the construction site. When the NFC chip is scanned by the entrance NFC scanning device at the entrance of the construction site, the entrance NFC scanning device writes a flag bit of access (eg, access flag bit) in the NFC chip. At the same time, the NFC chip sends an electrical signal (such as an electrical pulse) to the controller to activate the controller. The control unit then reads the device identifier ID_1 from the NFC chip and the device identifier ID_1 is transmitted to the communication module 12 via the communication bus (for example 12C bus).

In an embodiment in which the sensor unit is implemented as an NFC sensor unit (for example NFC chip) and the worker leaves the intelligent construction site, the electronic device 10 is in the operating mode. The worker, carrying the electronic device 10 in the operating mode, comes near the exit of the construction site. If the NFC chip is scanned by the exit NFC scanner at the exit of the construction site, the exit NFC scanner writes a flag bit of the exit (ex. exit flag bit) in the NFC chip. At the same time, the NFC chip sends an electrical signal (e.g. an electrical impulse) to the control unit. The control module 12 then reads the device identifier ID_1 from the NFC chip and the device identifier ID_1 is transmitted to the communication module 12 via the communication bus (for example 12C bus).

In an embodiment with realization of the sensor unit as a Bluetooth sensor unit and when the worker enters the intelligent construction site, the electronic device 10 is in the non-operational mode (at this time the Bluetooth sensor unit is in the low power consumption state, which means that the continuous measurement of the Bluetooth beacon with a preset frequency). The worker, carrying the electronic device 10 in the non-operational mode, comes near the entrance of the construction site. The Bluetooth sensor unit continuously measures the specific Bluetooth beacon at the preset frequency (e.g. marking with “activation and deactivation” to activate and deactivate devices). When the Bluetooth sensor unit senses a specific Bluetooth beacon, the Bluetooth sensor unit outputs an electrical signal to the controller to activate controller 0. The control unit then reads the device identifier ID_1 from the Bluetooth sensor unit and transmits the device identifier ID_1 to the communication module 12.

In an embodiment in which the sensor unit is implemented as a Bluetooth sensor unit and the worker leaves the intelligent construction site, the electronic device 10 is in the operating mode. The worker, carrying the electronic device 10 in the operating mode, comes near the exit of the construction site. The Bluetooth sensor unit continuously measures the specific Bluetooth beacon at the preset frequency. When the Bluetooth sensor unit measures a specific Bluetooth beacon, the control unit reads the device identifier ID_1 from the Bluetooth sensor unit and transmits the device identifier ID_1 to the communication module 12.

It should be understood that a key difference between the Bluetooth implementation and the NFC implementation is that in the Bluetooth implementation, the entry sensor and the exit sensor share the Bluetooth beacon (i.e. the specified Bluetooth Beacons) can be implemented, while in the NFC version the input sensor and the output sensor are each implemented as an input NFC scanning device and as an output NFC scanning device.

In block 302, the communication module 12 uses the uplink to send the device identifier ID_1 to the server 30 (cloud server or remote server) and waits for the command from the server 30.

In box 303, the worker is at the entrance or exit of the intelligent construction site, with the identity confirmation device 20 confirming the worker and generating the identification code ID_2 of the worker. The identifier ID_2 is, for example, the facial image, the iris image, the fingerprint or the voiceprint of the worker.

In block 304, the identity verification facility 20 makes a judgment as to whether or not the worker passes the verification based on the worker's identity identifier and previously stored identity information. For example, it is judged whether or not the worker has permission to enter the smart work site or to leave the smart work site.

If a positive judgment is made in block 304, the identity confirmation device 20 allows the worker to enter or leave the work site (block 305). In other words, once the identity confirmation by the identity confirmation device 20 has been passed, the worker is allowed to enter or leave the construction site.

If a negative judgment is made in block 304, the identity confirmation device 20 prohibits the worker from entering or leaving the work site (block 306). In other words, once the identity confirmation by the identity confirmation device 20 has failed, the worker is not allowed to enter or leave the construction site.

In field 307, the identity confirmation device 20 sends the identity identifier ID_2 to the server 30.

It should be understood that the present invention is not limited to a corresponding ordering of the two aspects of identifying the identity identifier of the worker and identifying the device identifier of the electronic device is. In other words, box 301 and box 303 can be executed in any order, for example box 301 and box 303 can be executed simultaneously.

In field 308 the server 30 receives the device identifier ID_1 originating from the electronic device 10 and the identity identifier ID_2 originating from the identity confirmation device 20 .

It is understood that the identity identifier ID_2 received by the server 30 comes from the input identity confirmation device or the output identity confirmation device, so that information can be obtained as to whether the worker wishes to enter the construction site or to leave the construction site and then order a to issue the correct control command.

In addition, in an implementation with NFC induction, the entry flagbit or exit flagbit written in the NFC chip can be transmitted to the server together with the device identifier. Thus, the server can obtain information on the worker's desire to enter or leave the site and issue a correct control command.

In box 309, the server 30 judges whether or not the received device identifier ID_1 matches the identity identifier ID_2. For example, it can thus be determined whether the worker is carrying the correct equipment (hard hat) or is accidentally carrying the equipment (hard hat) of a third party. For example, the server 30 assesses whether or not the device identifier ID_1 and the identity identifier ID_2 match by comparing device identifier ID_1 and identity identifier ID_2. The present invention does not provide for any specific limitation of the type of this comparison.

A match between device identifier and identity identifier can be understood as meaning that the device fitted with the electronic device and connected to the work site belongs (has been allocated) to the worker in question, which means that the worker carries the correct device connected to the work site.

A mismatch between the device identifier and the identity identifier can be understood as meaning that the device equipped with the electronic device and connected to the work site does not belong to the worker in question (has not been assigned), which means that the worker is carrying the wrong device connected to the work site (possibly received the wrong device at issue).

If the assessment in box 309 is positive (that is to say that the two identifiers match), the server 30 sends an activation or deactivation command to the communication module 12 (box 310).

In response to the activation or deactivation command received from the communication module 12 (box 312), the sensor control module 11 (box 313) executes the command originating from the server 30, i.e. activation or deactivation of the electronic device 10.

“Activation” can be understood to mean that the electronic device 10 is caused to enter the operational mode. Deactivation can be understood to mean that the electronic device 10 is caused to enter the non-operational mode.

In addition, in cases with an implementation of the sensor control unit that includes an NFC sensor unit and a control device, the control unit can be configured to control the electronic device 10 to enter the operating mode when reading an access flag bit and when reading an exit flag bit control the electronic device 10 to enter the non-operational mode. In other words, in some embodiments, the electronic device 10 may automatically enter the operational mode or the non-operational mode under control of the controller. For example, the control unit activates or deactivates the electronic device as a reaction to the entry flag bit or exit flag bit that has been read.

In one embodiment of the case mentioned, the NFC sensor unit is designed to output an electrical signal when the input NFC device scans and writes an access flag bit, which is used to activate the control device and the communication module. The control device is configured to read out the device identifier and the access flag bit in response to the received electrical signal from the N FC sensor unit. In response to the access flag bit read, the control unit controls the electronic device 10 to enter the operating mode.

In another embodiment of the case mentioned, the NFC sensor unit is designed to output an electrical signal when the output NFC device scans and writes an outgoing flag bit, which is used to activate the control device and the communication module. The control unit is designed to, in response to the received electric Signal from the NFC sensor unit to read the device ID and the outgoing flag bit. In response to the read outbound flag bit, the controller controls the electronic device 10 to enter the non-operational mode.

In the event of a negative assessment in field 309 (that is to say that the two identifiers do not match), the server 30 sends an activation or deactivation command to the communication module 12 and identifies the irregular event in question in order to enable follow-up.

Server 30 may also send alarm information to communication module 12 if block 309 is negative. The person carrying the electronic device 10 can thus be informed of the irregular incident (field 311).

If the determination in box 309 is negative, the server 30 can also send an intercept command to the entry authentication device or the exit authentication device to detect the worker when he is currently entering (or has already entered) the construction site or is currently exiting (or has already exited) the intercept construction site. For example, if the server 30 has determined that the device identifier originating from the electronic device does not match the identity identifier originating from the ingress authentication device, an intercept command is generated and the relevant intercept instruction is sent to the ingress authentication device. Although the worker may have already been allowed to enter the site after passing face recognition by the entrance identity verification device, upon receipt of the intercept command from the server 30 by the entrance identity verification device, action can be taken to intercept the worker already passing the entrance.

In one embodiment, the worker passed the entry authentication and entered the job site, failing the identity verification performed by the server. After the server 30 obtains information that the worker has already passed the entry verification of identity and entered the construction site and the electronic device 10 is still in sleep mode, the server 30 sends an activation command to the electronic device 10 to activate the electronic device 10 The server 30 also logs an irregular event related to the input in question. The electronic device 10 can thus continue to develop its intelligent functions on the construction site and the irregular incident can be tracked.

In another embodiment, the worker passed the initial identity verification and left the site, failing the identity verification performed by the server. When the server 30 makes a judgment based on the position signal (for example, GPS positioning signal) sent by the electronic device 10 that the electronic device 10 is already outside the construction site area (for example, the worker has already left the construction site with the electronic device) and itself if the electronic device 10 is still in the operating mode, the server 30 sends a deactivation command to the electronic device 30 to deactivate the electronic device 10. In addition, the server 30 logs an irregular event related to the outlet in question. In this way, the server can issue an instruction to deactivate the electronic device in the event that the identity comparison has not been passed, but the electronic device 10 has already been moved outside the construction site (for example together with the person carrying it). The electronic device 10 is thus in sleep mode when it is carried to the construction site again and the irregular incident can be tracked.

It can be seen that as soon as the worker enters the job site, the on-board electronic device can enter the operational mode, while as soon as the worker leaves the job site, the on-board electronic device can enter the non-operational mode. Even if the worker takes a wrong device (for example, a protective helmet provided with the electronic device), the control of the above mode switching can be performed. In addition, information about the irregular incident can be obtained immediately to take appropriate corrective measures. For example, the cause can be traced using the information logged by the server or video recordings.

In addition, by using the electronic device according to embodiments of the present invention, unnecessary power consumption of the battery can be reduced, which extends the life of the battery. Thus, the device housing with electronic equipment included (e.g. protective helmet housing) is not equipped with a charging connection (e.g. USB connection) for Requires charging and can achieve IP65 protection against intruding foreign objects.

It goes without saying that the mentioned NFC version and Bluetooth version are interchangeable. This means that an NFC version for realizing the control according to the present invention is just as possible as a Bluetooth version, with the two versions not being mutually exclusive.

The described embodiments are merely exemplary embodiments without implying a limitation of the present invention in this regard. The claims and their equivalents cover all forms, substitutions and modifications within the scope and purpose of the present invention.

Claims (16)

Electronic device (10) for an intelligent construction site, the electronic device (10) having an operating mode and a non-operating mode, the electronic device (10) comprising a sensor control module (11) and a communication module (12), wherein when the electronic device (10) is in the non-operating mode and a communication connection has been established between the sensor control module (11) and the input sensor of the intelligent construction site, the sensor control module (11) the electronic device (10) for switching from the non-operating mode to the operating mode controls; and when the electronic device (10) is in the operating mode and a communication link is established between the sensor control module and the exit sensor of the intelligent construction site, the sensor control module (11) the electronic device (10) for switching from the operating mode to the non-operating mode controls. Electronic device (10) according to claim 1 , wherein the communication module (12) has a communication connection with a server (30) and the sensor control module (11) is adapted to do so: in response to the establishment of the communication connection between the sensor control module (11) and the entrance sensor of the intelligent construction site or the exit - intelligent construction site sensor to control communication between the communication module (12) and the server (30); control the electronic device (10) to enter the operational mode when the communication module (12) receives an activation command from the server (30); and control the electronic device (10) to enter the non-operational mode when the communication module (12) receives a deactivation command from the server (30). Electronic device (10) according to claim 1 or 2 , wherein the communication module (12) is a far-field communication module, in particular a Lora communication module; the sensor control module (11) comprises a control device and a sensor unit with storage of the device identifier of the electronic device (10) and the sensor unit comprises an NFC sensor unit and/or a Bluetooth sensor unit. Electronic device (10) according to claim 3 , wherein the sensor unit is designed to output an electrical signal to the control unit when a communication connection is established with the input sensor or the output sensor; and the control device is designed to read out the device identifier as a reaction to the received electrical signal from the sensor unit and to control the communication module (12) to send the device identifier to the server (30). Electronic device (10) according to claim 3 or 4 , wherein the NFC sensor unit is designed such that when the input sensor establishes a communication connection with the input sensor, an access flag bit is written and an electrical signal is output to the control device; and wherein the control device is designed to read out the device identifier and the access flag bit as a reaction to the received electrical signal from the NFC sensor unit; wherein the control device is optionally also designed to control the electronic device (10) to enter the operating mode if an access flag bit is read out. Electronic device (10) according to any one of claims 3 - 5 , wherein the NFC sensor unit is designed such that when the output sensor establishes a communication connection with the output sensor, an outgoing flag bit is written and an electrical signal is output to the control device; and wherein the control unit is configured to read the device identifier and the outgoing flag bit as a reaction to the received electrical signal from the NFC sensor unit, wherein the control unit is optionally also configured to read the electronic device if an outgoing flag bit is read (10) control to enter non-operational mode. Electronic device (10) according to claim 3 or 4 , wherein the Bluetooth sensor unit is designed to emit an electrical signal when establishing a communication connection with the input sensor or the output sensor, the control unit being designed to respond to the electrical signal received from the Bluetooth sensor unit with the device identifier read and to control the communication module (12) for sending the device identifier to the server (30). Electronic device (10) according to any one of claims 3 - 7 , wherein if the device identifier does not match the identity identifier of the person carrying the electronic device (10), the communication module (12) also receives alarm information from the server (30) to indicate an irregular event related to the entry or exit, wherein the identifier of the entrainment serves to identify the entrainment; wherein the identity identifier optionally includes one or more of the following: facial image, iris image, fingerprint, or voiceprint of the companion. Electronic device (10) according to any one of Claims 1 - 8th wherein the electronic device (10) further comprises: a battery (13) serving as a power source for the electronic device (10); and position determination device, which serves to provide the position of the electronic device (10). Electronic device (10) according to any one of Claims 1 - 9 , wherein the electronic device (10) is incorporated in one of the following devices connected to the intelligent construction site: protective helmet, name tag or power tool. A control system (100) for an intelligent work site, comprising: electronic device (10) according to any one of Claims 1 - 10 , which is connected to the intelligent construction site; an identity certifier (20) comprising an input identity certifier and an egress identity certifier; and server (30), each of which has a communication connection with the electronic device (10) and the identity confirmation device (20), wherein, upon confirmation of the person carrying the electronic device (10) by the input identity confirmation device, the input identity confirmation device allows the person carrying it to pass the allowed entrance of the intelligent construction site and upon confirmation of the passenger by the exit identity verification device, the exit identity verification device allows the passenger to pass through the exit of the intelligent construction site; and the server (30) is designed to send an activation command for activating the electronic device (10) to the electronic device (10) upon receipt of a device identifier originating from the electronic device (10) and an identity identifier originating from the input identity confirmation device , wherein the server (30) sends a deactivation command for deactivating the electronic device (10) to the electronic device (10) upon receiving a device identifier originating from the electronic device (10) and an identity identifier originating from the initial identity confirmation device. control system (100) according to claim 11 , wherein the server (30) is also adapted to: judge whether or not the device identifier matches the identity identifier originating from the input identity confirmation device; if the result of the assessment is positive, to generate the activation command and to send the activation command to the electronic device (10); and if the result of the judgment is negative, generate the activation command and send the activation command to the electronic device (10) while logging an irregular event associated with the input; wherein, in the event of a negative judgment result, the server (30) optionally also sends alarm information to the electronic device (10) to indicate the irregular incident; a step further, if the judgment result is negative, the server (30) optionally also sends an intercept command to the ingress authentication device to intercept the carrier of the electronic device (10). control system (100) according to claim 11 or 12 , wherein the server (30) is further adapted to: judge whether or not the device identifier matches the identity identifier originating from the output identity confirmation device; if the result of the assessment is positive, the Deak generate activation command and send the deactivation command to the electronic device (10); and if the judgment result is negative, generate the deactivation command and send the deactivation command to the electronic device, wherein the logging of an irregular event related to the exit is performed, wherein if the judgment result is negative, the server (30) optionally also sends alarm information to the electronic device ( 10) to indicate the irregular occurrence, further in the event of a negative judgment result, the server (30) optionally also sends an intercept command to the originating identity verification device to intercept the carrier of the electronic device (10). Control system (100) according to any one of Claims 11 - 13 wherein the control system (100) further comprises an ingress NFC scanning device and an egress NFC scanning device; and the electronic device (10) comprises an NFC sensor unit for exchange with the input NFC scanning device and the output NFC scanning device, in which the device identifier of the electronic device (10) is stored. Control system (100) according to any one of Claims 11 - 13 wherein the control system (100) further comprises a Bluetooth beacon; and the electronic device (10) comprises a Bluetooth sensor for exchange with the Bluetooth beacon, in which the device identifier of the electronic device (10) is stored. Control system (100) according to any one of Claims 11 - 15 wherein the server (30) is further adapted to: receive the device position signal originating from the electronic device (10); and in the event of a determination based on the device position signal that the electronic device (10) is already outside of the smart site and in the operational mode, sending the deactivation command to the electronic device (10).

Images