Smart safety belt and monitoring method therefor
By integrating detection components and monitoring devices into the safety belt, the operator's wearing status can be monitored in real time, solving the problem of low intelligence level of existing safety belts and achieving the prevention of safety accidents.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- REMOC (HONG KONG) LTD
- Filing Date
- 2024-12-17
- Publication Date
- 2026-06-25
AI Technical Summary
The existing safety belts have a low level of intelligence and cannot monitor in real time whether the operators are wearing them correctly, leading to safety accidents.
Design an intelligent safety belt that integrates the belt body, main unit, detection components, hooks and buckles. The detection components collect data and transmit it to the server. The buckles and hooks use detection devices to monitor the operator's wearing status in real time and execute voice prompts or alarm commands through the main unit.
It enables real-time monitoring of operators, ensures the proper use of safety belts, avoids safety accidents, and improves safety and the accuracy of measurement data.
Smart Images

Figure CN2024140036_25062026_PF_FP_ABST
Abstract
Description
A smart seat belt and its monitoring method Technical Field
[0001] This invention relates to the field of seat belt technology, and more specifically, to an intelligent seat belt and its monitoring method. Background Technology
[0002] Currently, safety belts are typically required for working at heights to protect workers' safety. However, some workers have a weak sense of safety and operate improperly, such as not wearing safety belts or failing to properly fasten hooks or buckles after hooking them. These improper operations can easily lead to accidents.
[0003] Therefore, there is an urgent need to develop intelligent safety belts to monitor operators in real time, so that operators can use safety belts properly and avoid safety accidents. Technical issues
[0004] The technical problem to be solved by the present invention is that the existing safety belts have a low level of intelligence, making it impossible to know whether the operator is operating in accordance with the regulations, which can easily lead to safety accidents. In view of the above-mentioned defects of the existing technology, an intelligent safety belt and its monitoring method are provided. Technical solutions
[0005] The technical solution adopted by this invention to solve its technical problem is:
[0006] A smart safety belt is constructed, comprising a belt body, a main unit, a detection component for measuring height, a plurality of hooks and buckles; the main unit and the detection component are respectively disposed on the belt body; the main unit is electrically connected to the detection component and is used to collect data from the detection component and transmit the data to a server; the hooks and the buckles are respectively disposed on the belt body; the buckles are provided with buckle detection devices for detecting the status of the buckles; the hooks are provided with hook detection devices; the buckle detection devices and the hook detection devices are respectively communicatively connected to the detection component; the detection component includes a first detection component and a second detection component; the first detection component and the second detection component are respectively electrically connected to the main unit.
[0007] Furthermore, the belt includes a first plane and a second plane, which are arranged opposite to each other; the first detection component is disposed on the first plane and is used to detect the working height of the first plane; the second detection component is located on the second plane and is used to detect the working height of the second plane.
[0008] Furthermore, the first detection component includes a first housing, a data receiving device, an altitude measuring element, a temperature measuring element, a humidity measuring element, a work area detecting element, a detection communication device, an angular velocity detecting device, and a plurality of first detection elements; the data receiving device, the altitude measuring element, the temperature measuring element, the humidity measuring element, the work area detecting element, the detection communication device, the angular velocity detecting device, and the first detection elements are respectively disposed within the first housing; the detection communication device is electrically connected to the main unit; the data receiving device is communicatively connected to the buckle detection device and the hook detection device.
[0009] Furthermore, the second detection component includes a second housing, a hook connection indicator light, and several second detection elements; the hook connection indicator light and the second detection elements are respectively disposed on the second housing; the hook connection indicator light is communicatively connected to the hook detection device.
[0010] Furthermore, the strip has an intersection in the first plane, and the intersection is Y-shaped; the first detection component is located at the intersection.
[0011] Furthermore, the buckle includes an upper buckle, a lower buckle, and several leg buckles; the upper buckle, the lower buckle, and the leg buckles each include a base and a fastening component, the base and the fastening component being engaged or disengaged; the upper buckle, the lower buckle, and the leg buckles are each equipped with a buckle detection device, and the buckle detection device is communicatively connected to the data receiving device.
[0012] Furthermore, the upper buckle, the lower buckle, and several leg buckles are each provided with a first charging interface and a first power supply device for power supply, and the first power supply device is electrically connected to the buckle detection device.
[0013] Furthermore, the host is detachably mounted on the belt body. The host includes a housing, an anti-tamper device, a first communication device, a second communication device, a positioning device, a voice prompt device, an SOS button, a start button, a power supply component, a second charging interface, and several indicator lights. The anti-tamper device, the first communication device, the second communication device, the positioning device, the voice prompt device, and the power supply component are respectively located inside the housing. The start button, the second charging interface, and the indicator lights are respectively fixed to the housing. The power supply component is electrically connected to the anti-tamper device, the first communication device, the second communication device, the positioning device, the voice prompt device, and the indicator lights. The anti-tamper device, the first communication device, the second communication device, the positioning device, the voice prompt device, and the SOS button are respectively communicatively connected to the server.
[0014] Furthermore, the belt body is provided with a plurality of fixing rings, and the hook is provided with a locking hook, the locking hook passing through the fixing rings respectively.
[0015] Furthermore, the first plane and the second plane are respectively provided with adjusting buckles for adjusting the length of the belt, and the belt passes through the adjusting buckles respectively.
[0016] Constructing a monitoring method for smart seat belts, including:
[0017] Establish communication connections between the buckle detection device and the hook detection device and the detection component, respectively.
[0018] The detection component acquires detection data, and the status data of the buckle detection device and the hook detection device are also acquired.
[0019] The status data and the detection data are combined to obtain the summary data;
[0020] The summary data is obtained through the host and sent to a preset server;
[0021] The calculation is performed through the server to obtain the calculation result;
[0022] Based on the calculation results, match the corresponding voice prompt or alarm command in the preset database;
[0023] The host computer executes the voice prompt command or the alarm command.
[0024] Furthermore, before the step of acquiring detection data through the detection component and acquiring the status data of the buckle detection device and the hook detection device, the following steps are included:
[0025] The system uses a pre-set buckle detection device to determine whether the buckle is engaged.
[0026] If so, then it is determined that the attire is correct;
[0027] If not, it is determined that the clothing is worn incorrectly. Beneficial effects
[0028] The beneficial effects of this invention are as follows: the host unit is equipped with a detection component that can collect detection data and status data of hooks and buckles. The buckle detection device and hook detection device are equipped with a detection device that can detect the status of buckles and hooks to determine whether the buckle is engaged or the hook is caught. The data is transmitted to the server. After the server processes the data, it feeds back the results to the host unit for corresponding voice prompts or alarms. This allows for real-time monitoring of operators and provides voice prompts or alarms through the host unit to ensure that operators use safety belts correctly and avoid accidents.
[0029] This invention incorporates detection components on the safety belt body, enabling measurement of working height and working environment, thus enhancing intelligence and determining whether the operator is working in a safe environment, thereby improving the safety of the safety belt. Furthermore, the inclusion of a first detection component and a second detection component improves the accuracy of the measurement data. Attached Figure Description
[0030] Figure 1 is an overall structural diagram of a smart seat belt according to an embodiment of the present invention;
[0031] Figure 2 is a schematic diagram of the method steps of a smart seat belt monitoring method according to an embodiment of the present invention;
[0032] Figure 3 is a perspective view of a host computer according to an embodiment of the present invention;
[0033] Figure 4 is a perspective view of a hook according to an embodiment of the present invention;
[0034] Figure 5 is a three-dimensional schematic diagram of a buckle in one embodiment of the present invention;
[0035] Figure 6 is a structural block diagram of the first detection component in an embodiment of the present invention;
[0036] Figure 7 is a structural block diagram of the second detection component in one embodiment of the present invention;
[0037] Figure 8 is a structural block diagram of the host in an embodiment of the present invention;
[0038] Figure 9 is a rear view schematic diagram of a smart seat belt according to an embodiment of the present invention.
[0039] Labeling Explanation: Belt Body 1, Main Unit 2, Detection Component 3, Hook 4, Buckle 5, Buckle Detection Device 6, Hook Detection Device 7, First Detection Component 81, Second Detection Component 82, First Plane 11, Second Plane 12, First Housing 811, Data Receiving Device 812, Altitude Measuring Component 813, Temperature Detection Component 814, Humidity Detection Component 815, Working Area Detection Component 816, Detection and Communication Device 817, Angular Velocity Detection Device 818, First Detection Component 819, Second Housing 821 Hook connection indicator light 822, second detector 823, intersection 111, upper buckle 51, lower buckle 52, leg buckle 53, seat 511, fastening part 512, first charging interface 514, outer shell 21, anti-tamper device 22, first communication device 23, second communication device 24, positioning device 25, voice prompt device 26, distress button 27, start button 28, power supply part 29, second charging interface 211, indicator light 212, fixing ring 13, locking hook 14, adjusting buckle 15. Embodiments of the present invention
[0040] To make the objectives, technical solutions, and advantages of this application clearer, the following detailed description is provided in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the scope of this application.
[0041] Please refer to Figure 1. This invention proposes an intelligent safety belt, including a belt body 1, a main unit 2, a detection component 3 for measuring height, several hooks 4, and buckles 5. The main unit 2 and the detection component 3 are respectively disposed on the belt body 1. The main unit 2 is electrically connected to the detection component 3 and is used to collect data from the detection component 3 and transmit the data to a server. The hooks 4 and buckles 5 are respectively disposed on the belt body 1. The buckles 5 are provided with a buckle detection device 6 for detecting the status of the buckles 5. The hooks 4 are provided with hook detection devices 7. The buckle detection devices 6 and hook detection devices 7 are respectively communicatively connected to the detection component 3. The detection component 3 includes a first detection component 81 and a second detection component 82. The first detection component 81 and the second detection component 82 are respectively electrically connected to the main unit 2.
[0042] In this embodiment, the main unit 2 is located on the front of the belt body 1, positioned on the left chest after wearing, and above the adjustment buckle. It is detachable from the belt body 1 and is a movable component used to collect data from the detection component 3 and transmit the data to the server. Hooks 4 and buckles 5 are respectively located on the belt body 1. Hooks 4 are equipped with hook detection devices 7 to detect whether they are hooked, and buckles 5 are equipped with buckle detection devices 6 to detect whether they are locked, fastened, or loose. Hook detection devices 7 and buckle detection devices 6 are communicatively connected to the detection component. In this embodiment, hook detection devices 7 and buckle detection devices 6 are wirelessly connected to the detection component 3 via 2.4GHz wireless communication. The detection devices are wired to the main unit 2, enabling them to send status data of hook detection devices 7 and buckle detection devices 6 to the main unit 2. By detecting the status of hooks 4 and buckles 5, it is possible to determine whether the operator is wearing a safety belt and whether it is worn correctly during high-altitude operations, thus avoiding safety hazards and enabling real-time monitoring of the operator. The detection component 3 includes a first detection component 81 and a second detection component 82, and the first detection component 81 and the second detection component 82 are electrically connected to the host 2 respectively, and can transmit data to the host 2 through a data cable.
[0043] In one embodiment, the belt body 1 includes a first plane 11 and a second plane 12, which are arranged opposite to each other; a first detection component 81 is disposed on the first plane 11 and is used to detect the working height of the first plane 11; a second detection component 82 is located on the second plane 12 and is used to detect the working height of the second plane 12.
[0044] Specifically, as shown in Figure 9, the first plane 11 is the back of the belt body 1; as shown in Figure 1, the second plane 12 is the front of the belt body 1. The first detection component 81 is located on the back of the belt body 1, positioned in the middle of the shoulder area after being worn, and detects the working height on the back; simultaneously, it can collect data from the buckle detection device 6 and the hook detection device 7. The second detection component 82 is located on the front of the belt body 1, positioned on the right chest area after being worn, and can measure the working height on the front of the belt body 1.
[0045] Please refer to Figure 3. The first detection component 81 includes a first housing 811, a data receiving device 812, an altitude measuring element 813, a temperature measuring element 814, a humidity measuring element 815, a work area detecting element 816, a detection communication device 817, an angular velocity detecting device 818, and several first detection elements 819. The data receiving device 812, the altitude measuring element 813, the temperature measuring element 814, the humidity measuring element 815, the work area detecting element 816, the detection communication device 817, the angular velocity detecting device 818, and the first detection elements 819 are respectively disposed inside the first housing 811. The detection communication device 817 is electrically connected to the host 2. The data receiving device 812 is communicatively connected to the buckle detection device 6 and the hook detection device 7.
[0046] In specific implementation: the safety belt mainly detects the height of the back of the safety belt through the first detection component 81. Specifically, the data receiving device 812, altitude measuring component 813, temperature detection component 814, humidity detection component 815, work area detection component 816, detection communication device 817, angular velocity detection device 818, and the first detection component 819 are respectively housed within the first housing 811. The data receiving device 812 is a data receiving module. The hook detection device 7 and the buckle detection device 6 are matched with the data receiving module via 2.4GHz wireless communication. After matching, the status data of the hook detection device 7 and the buckle detection device 6 are received, such as whether the buckle 5 is locked; then the data is transmitted to the host 2. In a specific embodiment, the altitude measuring component 813 is an altimeter and is used to measure the altitude. The temperature detection component 814 is a thermometer and is used to measure the temperature around the safety belt; the humidity detection component 815 is a hygrometer and is used to detect the humidity. Equipped with an altitude measuring device 813, a temperature detection device 814, and a humidity detection device 815, it can determine the operator's working environment, prevent the operator from working in harsh environments, and avoid accidents.
[0047] In one specific embodiment, the work area detection component 816 is UWB (Ultra Wide Band), which can divide the high-altitude work area into zones and perform real-time position analysis of the workers to accurately determine whether there is a risk in the area where the workers are located, ensuring the safety of high-altitude workers and reducing the accident rate. In another specific embodiment, the detection and communication device 817 is equipped with a 4G communication module, i.e., the fourth generation mobile information system, and is wiredly connected to the host 2, enabling data transmission to the host 2 via a data cable. In another specific embodiment, the angular velocity detection device 818 is a gyroscope, which can detect the angular velocity of the workers to determine whether a fall from height has occurred. The first detection component 819 is a laser sensor, which can detect height. The first detection component 81 can collect data on the temperature, humidity, altitude, and status of the hook detection device 7 and the buckle detection device 6 of the worker's working environment, and the work area detection component 816 can distinguish between the work area and the rest area.
[0048] Please refer to Figure 4. The second detection component 82 includes a second housing 821, a hook connection indicator light 822, and several second detection elements 823. The hook connection indicator light 822 and the second detection elements 823 are respectively disposed on the second housing 821. The hook connection indicator light 822 is communicatively connected to the hook detection device 7.
[0049] In practical implementation: the second detection component 82 is an auxiliary detection device that assists the first detection component 81 in detecting the height of the front of the safety belt. When there are obstructions during high-altitude operations, the first detection component 81 alone may result in inaccurate data or measurement results. Adding the second detection component 82 to the first detection component 81 further enhances the measurement of the working height. It also includes a hook connection indicator light 822. After the hook detection device 7 and the hook connection indicator light 822 establish a communication connection, they wirelessly pair and connect, and the light illuminates upon successful connection, indicating whether a connection has been established. In another specific embodiment, the safety belt may be equipped with a differential extension rope. In this case, the second detection component 82 also includes a differential extension rope connection indicator light, which communicates with the differential extension rope. Once connected, the differential extension rope indicator light illuminates.
[0050] Please refer to Figure 1. The belt body 1 has a cross portion 111 in the first plane 11, and the cross portion 111 is Y-shaped; the first detection component 81 is located in the cross portion 111.
[0051] In practical implementation: the back of the belt body 1 is provided with a cross portion 111, which has a Y-shaped structure and can have a higher restraining force. The first detection component 81 is located at the cross portion 111, that is, in the middle position of the shoulder of the back of the seat belt.
[0052] Please refer to Figure 5. The buckle 5 includes an upper buckle 51, a lower buckle 52, and several leg buckles 53. The upper buckle 51, the lower buckle 52, and the leg buckles 53 each include a base 511 and a fastening element 512. The base 511 and the fastening element 512 are engaged or disengaged. The upper buckle 51, the lower buckle 52, and the leg buckles 53 are each equipped with a buckle detection device 6, which is communicatively connected to the data receiving device 812.
[0053] In practical implementation: the upper buckle 51 is located directly above the lower buckle 52, and together with the lower buckle 52, it can fasten the seat belt. There are two leg buckles 53, which can be fastened to the left leg and the right leg respectively. Multiple buckles 5 can securely wear the seat belt on the human body.
[0054] Specifically, the upper buckle 51, lower buckle 52, and leg buckle 53 each include a seat body 511 and a fastening member 512. When the seat body 511 is engaged with the fastening member 512, the seat belt is worn on the body. The upper buckle 51, lower buckle 52, and leg buckle 53 are each equipped with a buckle detection device 6, and are wirelessly connected to the data receiving device 812. The buckle detection device 6 can be a contact sensor or a normally closed switch, capable of detecting whether the buckle 5 is engaged. When it is a contact sensor, it is located on the seat body 511 or the fastening member 512. After the seat body 511 contacts the fastening member 512, a sensing signal is generated to determine whether it is engaged. If it is a normally closed switch, an electrical signal is generated after the buckle 5 is released and sent to the first detection component 81.
[0055] Please refer to Figures 1 and 5. The upper buckle 51, the lower buckle 52 and several leg buckles 53 are respectively provided with a first charging interface 514 and a first power supply device for power supply. The first power supply device is electrically connected to the buckle detection device 6.
[0056] In specific implementation: the upper buckle 51, lower buckle 52, and leg buckle 53 are each provided with a first charging interface 514 to charge the buckle detection device 6. In one specific embodiment, the first charging interface 514 is a USB Type-C charging interface and is electrically connected to the first power supply device, enabling charging after connection to a data cable. The first power supply device is a battery that can supply power to the buckle detection device 6, and the first power supply device has a pre-programmed battery life algorithm, such as range = \frac{battery voltage \times battery capacity \times speed}{motor power}; it can perform power management on the battery, enabling the battery to have a long battery life function, that is, when it is not used for a long time, it enters a sleep state.
[0057] Please refer to Figures 3 and 5. The main unit 2 is detachably mounted on the belt body 1. The main unit 2 has a housing 21, an anti-tamper device 22, a first communication device 23, a second communication device 24, a positioning device 25, a voice prompt device 26, an emergency call button 27, a start button 28, a power supply component 29, a second charging interface 211, and several indicator lights. The anti-tamper device 22, the first communication device 23, the second communication device 24, the positioning device 25, the voice prompt device 26, and the power supply component 29 are respectively located inside the housing 21. The start button 28, the second charging interface 211, and the indicator lights are respectively fixed to the housing 21. The power supply component 29 is electrically connected to the anti-tamper device 22, the first communication device 23, the second communication device 24, the positioning device 25, the voice prompt device 26, and the indicator lights. The anti-tamper device 22, the first communication device 23, the second communication device 24, the positioning device 25, the voice prompt device 26, and the emergency call button 27 are respectively connected to the server for communication.
[0058] In practical implementation: the anti-tamper device 22, the first communication device 23, the second communication device 24, the positioning device 25, the voice prompt device 26, and the power supply component 29 are respectively housed within the outer casing 21; the back of the outer casing 21 also has multiple fixing holes to fix the main unit 2 to the strap 1, and the fixing method can be screw thread connection. After being worn, it is located on the left chest of the human body and above the adjustment buckle. The main unit 2 can also be removed from the strap 1 by removing the screws. The main unit 2 is also equipped with an anti-tamper device 22. Specifically, a contact sensor with authorization is provided on the back of the main unit 2. When the main unit 2 is in an unauthorized state and is disassembled, the sensor will detect it and generate an electrical signal. At this time, the anti-tamper device 22 will lock the main unit 2, making the main unit 2 unable to be used normally. When the main unit 2 is in an authorized state, the main unit 2 can be removed from the strap 1.
[0059] The first communication device 23 is a 4G communication module, capable of real-time communication with the server and transmitting data to the server; simultaneously, it can acquire real-time status data of the hook detection device 7 and the buckle detection device 6. The second communication device 24 is a LoRa communication module, which, through spread spectrum modulation, can extend signal bandwidth to improve transmission distance and anti-interference capabilities. In areas without 4G signals, LoRa communication can be used. The positioning device 25 is a GPS module (Global Positioning System), capable of locating the operator to determine their precise position. The voice prompt device 26 can be a speaker or buzzer, capable of broadcasting voice prompts sent by the server or issuing alarms. The distress button 27 is located on the outer casing 21; pressing the distress button 27 sends a distress signal to the server or issues an alarm to promptly rescue the operator. The start button 28 is electrically connected to the first communication device 23, the second communication device 24, the positioning device 25, the voice prompt device 26, the SOS button 27, the start button 28, the power supply component 29, and the indicator lights. Pressing the start button 28 activates the first communication device 23, the second communication device 24, the positioning device 25, the voice prompt device 26, the SOS button 27, the start button 28, the power supply component 29, and the indicator lights. The power supply component 29 is a battery used for power supply. Similarly, the host 2 has a battery power-saving management system with a battery life algorithm. When not in use for a long time, it will enter a sleep state to achieve long battery life. The host 2 is wiredly connected to the first detection component 81 and the second detection component 82, collecting data from the first detection component 81 and the second detection component 82 via a data cable, and simultaneously supplying power to the first detection component 81 and the second detection component. The second charging interface 211 can be a USB Type-C charging interface, which can charge the power supply component 29. Indicator light 212 includes a power indicator light, a working indicator light, and a signal strength indicator light. The power indicator light can indicate the power level by changing the light color; the working indicator light can indicate to the operator whether the host 2 is operating normally by turning it on or off; there are multiple signal strength indicator lights, which are electrically connected to the first communication device 23 and the second communication device 24. The number of lights indicates the signal strength. For example, if there are four signal strength indicator lights, all four signal indicator lights will be lit when the signal is full, and one or two signal strength indicator lights will be lit when the signal is weak, so that the operator can know the signal strength in the area and avoid the host 2 losing connection with the server.
[0060] Please refer to Figures 1 and 4. The belt body 1 is provided with several fixing rings 13, and the hook 4 is provided with locking hooks 14, which pass through the fixing rings 13 respectively.
[0061] In specific implementation: the belt body 1 is provided with two fixing rings 13, located on the left and right sides respectively. In one specific embodiment, the fixing rings 13 are D-shaped rings, and the locking hooks 14 of the hooks 4 pass through the D-rings respectively. When the hooks 4 are not needed, they can be suspended on the D-rings for carrying.
[0062] Please refer to Figure 1. The first plane 11 and the second plane 12 are respectively provided with adjustment buckles for adjusting the length of the belt body 1, and the belt body 1 passes through the adjustment buckles respectively.
[0063] In practical implementation: Adjustment buckles are provided on both the back and front of the belt body 1. The adjustment buckles are hollow and have multiple crossbars in the middle. The belt body 1 passes through the adjustment buckles and is arranged around the crossbars. When the length of the belt body 1 needs to be adjusted, it can be adjusted by pulling the adjustment buckles onto the belt body 1 to adapt to different working environments or the needs of different workers.
[0064] Please refer to Figure 2. This invention proposes a monitoring method for intelligent seat belts, including:
[0065] S1, establish communication connections between the buckle detection device 6 and the hook detection device 7 and the detection component 3 respectively;
[0066] S2, acquire detection data through detection component 3, and acquire status data of buckle detection device 6 and hook detection device 7;
[0067] S3, summarize the status data and detection data to obtain the summary data;
[0068] S4, obtain the summary data through host 2, and send the summary data to the preset server;
[0069] S5 performs calculations through the server to obtain the results;
[0070] S6, based on the calculation results, match the corresponding voice prompt command or alarm command in the preset database;
[0071] S7 executes voice prompts or alarm commands through host 2.
[0072] In this embodiment, the data receiving device 812 of the detection component 3 is equipped with a 2.4GHz wireless transmission module, enabling short-range wireless transmission. The 2.4GHz wireless transmission module establishes communication connections between the buckle detection device 6 and the hook detection device 7 and the detection component 3, respectively. After the connection is established, the data receiving device 812 can receive the status data of the hook detection device 7 and the buckle detection device 6. The status data and detection data are then summarized to obtain summarized data. Since the first detection component 81 is wired to the host 2, after summarizing the status data and detection data, it is transmitted to the host 2 via a data cable. The host 2 communicates with the server through the first communication device 23 or the second communication device 24 and sends the summarized data to the server. After calculation, the server obtains the calculation result. If the obtained status data of the buckle detection device 6 is not fastened, and the status data of the hook detection device 7 is also not fastened, the calculated result is that the device is not properly worn. Then, based on the calculation result, a voice prompt command or alarm command is matched in a preset database and fed back to the host 2. Finally, the host 2 executes the voice prompt command or alarm command. In one specific embodiment, if the preset database indicates that the item is not worn correctly, an alarm will be issued for three seconds. Upon receiving the alarm command, host 2 will issue a three-second alarm. This allows for timely alerts and prevents safety incidents.
[0073] In one embodiment, before the step of acquiring detection data through the detection component 3 and acquiring the status data of the buckle detection device 6 and the hook detection device 7, the following steps are included:
[0074] The system uses a pre-set buckle detection device 6 to determine whether the buckle 5 is engaged.
[0075] If yes, it is determined that the garment is worn correctly; if no, it is determined that the garment is worn incorrectly.
[0076] In practical implementation: Detection component 3 is used to detect the operator's working height and obtain detection data. Simultaneously, the buckle detection device 6 determines whether the buckle 5 is engaged or secure. If engaged, it is determined that the buckle is correctly worn. If not engaged, it is determined that the buckle is incorrectly worn. After the determination, the results are sent to detection component 3.
[0077] It should be noted that, in this document, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, apparatus, article, or method that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, apparatus, article, or method. Unless otherwise specified, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, apparatus, article, or method that includes that element.
[0078] The above are merely preferred embodiments of this application and do not limit the patent scope of this application. Any equivalent structural or procedural transformations made using the content of this application's specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this application.
Claims
1. An intelligent safety belt comprising a belt body; characterized in that, The application relates to a height measuring device, which comprises a main machine, a probe assembly for measuring height, a plurality of hooks and buckles. The main machine and the probe assembly are arranged on the belt body respectively. The main machine is electrically connected with the probe assembly, and is used for collecting data of the probe assembly and transmitting the data to a server. The hooks and the buckles are arranged on the belt body respectively. The buckle detection device is arranged on the buckle and is used for detecting the state of the buckle. The hook detection device is arranged on the hook. The buckle detection device and the hook detection device are respectively connected with the probe assembly. The probe assembly comprises a first probe assembly and a second probe assembly.
2. The smart seat belt of claim 1, wherein, The first probe assembly and the second probe assembly are respectively electrically connected with the main machine. The belt body comprises a first plane and a second plane, and the first plane and the second plane are oppositely arranged. The first probe assembly is arranged on the first plane and is used for detecting the working height of the first plane.
3. The smart seat belt of claim 2, wherein, The second probe assembly is arranged on the second plane and is used for detecting the working height of the second plane. The first probe assembly comprises a first shell, a data receiving device, an altitude measuring element, a temperature detecting element, a humidity detecting element, a working area detecting element, a probe communication device, an angular velocity detecting device and a plurality of first probe elements. The data receiving device, the altitude measuring element, the temperature detecting element, the humidity detecting element, the working area detecting element, the probe communication device, the angular velocity detecting device and the first probe elements are arranged in the first shell respectively.
4. The smart seat belt of claim 1, wherein, The probe communication device is electrically connected with the main machine, and the data receiving device is connected with the buckle detection device and the hook detection device.
5. The smart seat belt of claim 2, wherein, The second probe assembly comprises a second shell, a hook connection indicating lamp and a plurality of second probe elements. The belt body is provided with a cross section in the first plane, and the cross section is in a Y shape.
6. The smart seat belt of claim 3, wherein, The first probe assembly is arranged on the cross section. The buckle comprises an upper buckle, a lower buckle and a plurality of leg buckles. The upper buckle, the lower buckle and the leg buckles respectively comprise a seat body and a buckling element, and the seat body and the buckling element are buckled or separated.
7. The smart seat belt of claim 6, wherein, The upper buckle, the lower buckle and the leg buckles are respectively provided with buckle detection devices, and the buckle detection devices are respectively connected with the data receiving device.
8. The smart seat belt of claim 1, wherein, The upper buckle, the lower buckle and the plurality of leg buckles are respectively provided with a first charging interface and a first power supply device for power supply, and the first power supply device is electrically connected with the buckle detection device. The main machine is detachably arranged on the belt body, and the main machine is provided with a shell, an anti-disassembly device, a first communication device, a second communication device, a positioning device, a voice prompting device, a help button, a starting button, a power supply element, a second charging interface and a plurality of indicating lamps. The anti-disassembly device, the first communication device, the second communication device, the positioning device, the voice prompting device and the power supply element are arranged in the shell respectively. The starting button, the second charging interface and the indicator light are respectively fixed to the shell; The power supply member is respectively electrically connected with the anti-disassembly device, the first communication device, the second communication device, the positioning device, the voice prompt device and the indicator light; The anti-disassembly device, the first communication device, the second communication device, the positioning device, the voice prompt device and the help-seeking button are respectively in communication connection with the server.
9. The smart seat belt of claim 1, wherein, The belt body is provided with a plurality of fixing rings, and the hook is provided with a lock hook which penetrates through the fixing ring.
10. The smart seat belt of claim 2, wherein, The first plane and the second plane are respectively provided with an adjusting buckle for adjusting the length of the belt body, and the belt body penetrates through the adjusting buckle.
11. A method of monitoring a smart seat belt, characterized by, Comprising: The buckle detection device and the hook detection device are respectively in communication connection with the detection assembly; The detection data is acquired through the detection assembly, and the state data of the buckle detection device and the hook detection device is acquired; The state data and the detection data are summarized to obtain summary data; The summary data is acquired through the host, and the summary data is sent to a preset server; The server is used for calculation to obtain a calculation result; According to the calculation result, a corresponding voice prompt instruction or an alarm instruction is matched in a preset database; The host is used for executing the voice prompt instruction or the alarm instruction.
12. The method of monitoring a smart seat belt of claim 11, wherein, Before the step of acquiring the detection data through the detection assembly and acquiring the state data of the buckle detection device and the hook detection device, comprising: The buckle detection device is used for judging whether the buckle is buckled or not; If yes, it is determined that the wearing is correct; If no, it is determined that the wearing is incorrect.