A safety monitoring device for mine electromechanical

Abstract

The utility model relates to the technical field of mine electromechanical, and disclose a kind of safety monitoring device for mine electromechanical, including control cabinet, conversion component includes multiple partition plates being arranged in the inside of control cabinet, multiple partition plates one end are provided with mounting frame, and mounting frame inside is provided with loading bin;Loading bin inside is provided with carousel, and the outer wall of carousel is provided with multiple cavities, and the inside of carousel is provided with inner shaft, and the outer wall of inner shaft is provided with multiple telescopic lines, and the other end of telescopic line is provided with conversion block, and the outer wall of conversion block is provided with connector;Multiple partition plates one side are provided with connecting seat, and the inside of connecting seat is provided with locating groove, and the inner wall of locating groove is provided with wiring hole.The utility model is through installing multiple intermediate, and can be flexibly adjusted according to the monitoring device of different equipment, realizes the connection of different data unified integration with control cabinet, ensures the stability and precision of data transmission, and realizes the collection and management of different equipment data.

Description

Technical Field

[0001] This utility model relates to the field of mining electromechanical technology, specifically a safety monitoring device for mining electromechanical applications. Background Technology

[0002] Mining electromechanical equipment is one of the core technologies in mining production. Its performance and management level directly affect the mine's production efficiency, safety, and economic benefits. With continuous technological advancements, mining electromechanical equipment will be constantly updated and improved, providing strong support for the sustainable development of mines. Mining electromechanical equipment plays a multifaceted and vital role in mining production, not only improving production efficiency and economic benefits but also ensuring production safety and environmental sustainability. It is an indispensable core technology in modern mining production.

[0003] Safety monitoring devices for mine electromechanical equipment are an important means of ensuring safe production in mines. Through various sensors and monitoring systems, these devices can monitor the operating status of equipment and environmental parameters in real time, promptly identify and address safety hazards, and effectively prevent accidents from occurring.

[0004] When conducting safety monitoring of mine electromechanical equipment, the individual detection sensor data of various devices are integrated into a comprehensive monitoring system to achieve centralized management and real-time monitoring. However, in actual management, due to compatibility issues between different monitoring sensors, it may be impossible to seamlessly connect with the central monitoring system, resulting in data transmission interruption or errors, which affects the accuracy and normal operation of monitoring. Utility Model Content

[0005] The purpose of this utility model is to provide a safety monitoring device for mine electromechanical equipment, in order to solve the problem mentioned in the background art that the different sensor models of monitoring devices used for different equipment in mines lead to incompatibility with the central control center during centralized data transmission and integration, resulting in errors in the data interpretation process and affecting the accuracy of the monitoring data.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a safety monitoring device for mine electromechanical equipment, comprising a control console, wherein the control console is provided with a conversion component for compatibility with sensor data from different monitoring equipment, the conversion component comprising multiple partitions disposed on the inner side of the control console, each of the multiple partitions having a mounting frame at one end, and a loading compartment disposed inside the mounting frame;

[0007] The loading compartment is equipped with a turntable inside. The outer wall of the turntable is provided with multiple cavities. The turntable is equipped with an inner shaft inside. The outer wall of the inner shaft is provided with multiple telescopic lines. The other end of the telescopic lines is provided with a conversion block. The outer wall of the conversion block is provided with a connector.

[0008] Each of the partition plates is provided with a connecting seat on one side, and the connecting seat is provided with a positioning groove inside, and the inner wall of the positioning groove is provided with a wiring hole.

[0009] Preferably, the array of multiple partition plates is distributed inside the console, the mounting frame is located at one end of the partition plate and is embedded and connected to the inner wall of the console, and the loading compartment has an open structure.

[0010] Preferably, the turntable is located inside the loading chamber of the mounting frame and is rotatably connected to the inner wall of the loading chamber via a connecting shaft, and a plurality of cavities are distributed in a ring on the outer wall of the turntable.

[0011] Preferably, the inner shaft is located inside the turntable and is coaxially connected to the turntable, and communicates with multiple cavities. A signal receiver is provided inside the inner shaft, and one end of each of the multiple telescopic cables is connected to the inner shaft, and the other end is connected to the conversion block.

[0012] Preferably, the connecting seat is located on one side of the mounting frame, and the positioning groove on one side of the connecting seat is corresponding to and communicates with the loading compartment inside the mounting frame.

[0013] Preferably, the conversion block is located inside the cavity and is slidably connected to the inner wall of the cavity. The conversion block can be pulled out from the cavity and extended into the positioning groove inside the connecting seat, and is slidably connected to the positioning groove so that the connector at one end is inserted into the wiring hole on the inner wall of the positioning groove.

[0014] Compared with the prior art, the beneficial effects of this utility model are:

[0015] 1. The control console is divided into multiple control areas according to different types of mining equipment. An installation frame is set between each control area, and multiple middleware that can be adapted to different monitoring equipment models are placed in the installation frame. The middleware acts as a bridge between different devices and systems, providing functions such as data conversion, protocol adaptation and communication management. This enables unified data collection and management when facing different monitoring equipment, avoids data errors and improves the effect of data integration.

[0016] 2. By centrally storing multiple different middleware components in the mounting frame, and flexibly removing unnecessary middleware components via a turntable and connecting them to the connector on the control panel, data transmission is ensured, allowing for flexible adjustments when facing different monitoring signals and improving the control panel's compatibility with different monitoring devices.

[0017] This invention integrates various data sources with a control console by installing multiple middleware components and making flexible adjustments based on the monitoring devices of different equipment. This ensures stable and accurate data transmission and enables the collection and management of data from different devices. Attached Figure Description

[0018] Figure 1This is an overall isometric view of the present invention;

[0019] Figure 2 This is an enlarged view of part A of this utility model;

[0020] Figure 3 This is a breakdown diagram of the internal structure of the mounting frame of this utility model;

[0021] Figure 4 This is a structural diagram of the internal structure of the connector of this utility model.

[0022] In the diagram: 1. Control console; 2. Divider plate; 3. Mounting frame; 301. Loading compartment; 4. Turntable; 401. Cavity; 402. Inner shaft; 5. Telescopic line; 6. Converter block; 601. Connector; 7. Connecting seat; 8. Positioning groove; 801. Wiring hole. Detailed Implementation

[0023] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0024] All devices in this application adopt conventional models in the prior art, and the control method is through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art, which is common knowledge in the field, so this application will not explain it in detail.

[0025] Please see the appendix Figure 1-4 As shown, a safety monitoring device for mining electromechanical equipment includes a control console 1. The control console 1 is equipped with a conversion component for compatibility with sensor data from different monitoring devices. The conversion component includes multiple partitions 2 disposed inside the control console 1, which are used to divide the control console 1 into multiple areas according to the type of mining equipment. Each partition 2 is provided with a mounting frame 3 at one end for mounting a turntable 4 and a conversion block 6, so that they are stored on one side of different control areas of the control console 1 for easy and quick operation. The mounting frame 3 is provided with a loading bin 301.

[0026] Multiple partition plates 2 are arrayed inside the control console 1. The mounting frame 3 is located at one end of the partition plate 2 and is embedded and connected to the inner wall of the control console 1. The loading chamber 301 is an open structure. The turntable 4 is located inside the loading chamber 301 of the mounting frame 3 and is rotatably connected to the inner wall of the loading chamber 301 through a connecting shaft. Multiple cavities 401 are distributed in a ring on the outer wall of the turntable 4.

[0027] In this embodiment, the operating space of the control console 1 can be divided into multiple control areas corresponding to different types of mining equipment by the partition plate 2, which facilitates the signal integration or management control of the monitoring devices of different types of mining equipment.

[0028] Example 2: This example is an improvement on Example 1. For details, please refer to [link / reference]. Figures 2-4 The loading chamber 301 is equipped with a turntable 4, which can rotate within the loading chamber 301 of the mounting frame 3 and store multiple conversion blocks 6. The outer wall of the turntable 4 is provided with multiple cavities 401 for storing the conversion blocks 6 and positioning the angle of the conversion blocks 6 when stored. The turntable 4 is equipped with an inner shaft 402, and the outer wall of the inner shaft 402 is provided with multiple telescopic cables 5. One end of the telescopic cable 5 is connected to a power source, and the other end is connected to the conversion block 6, thereby supplying power to the intermediate component inside the conversion block 6. The other end of the telescopic cable 5 is provided with the conversion block 6, and the conversion block 6 is equipped with an intermediate component (different types of intermediate components can adapt to the data of different monitoring devices, thereby performing data conversion, protocol adaptation and communication management functions, which facilitates the connection of the data after processing and conversion to the control console 1). The outer wall of the conversion block 6 is provided with a connector 601, which facilitates the electrical connection between the conversion block 6 and the connecting seat 7.

[0029] Each of the multiple partition plates 2 has a connecting seat 7 on one side. The connecting seat 7 is connected to the control console 1 by telecommunications, so that the conversion block 6 can transmit the converted data to the control console 1 for data analysis and processing, and for integrated management. The connecting seat 7 has a positioning groove 8 inside, which is used to position the angle of the conversion block 6 during installation. The inner wall of the positioning groove 8 has a wiring hole 801.

[0030] The inner shaft 402 is located inside the turntable 4 and is coaxially connected to the turntable 4. It is also connected to multiple cavities 401. A signal receiver is installed inside the inner shaft 402. One end of multiple telescopic cables 5 is connected to the inner shaft 402, and the other end is connected to the conversion block 6. The connecting seat 7 is located on one side of the mounting frame 3, and the positioning groove 8 on one side of the connecting seat 7 is correspondingly connected to the loading chamber 301 in the mounting frame 3. The conversion block 6 is located inside the cavity 401 and is slidably connected to the inner wall of the cavity 401. The conversion block 6 can be pulled out from the cavity 401 and extended into the positioning groove 8 inside the connecting seat 7. It is slidably connected to the positioning groove 8 so that the connector 601 at one end is inserted into the wiring hole 801 on the inner wall of the positioning groove 8.

[0031] In this embodiment: when facing signals from different monitoring devices, the turntable 4 can be controlled to rotate within the mounting frame 3 according to the data type, thereby driving the conversion block 6, which has the corresponding intermediate component installed, to rotate to the opening area of ​​the mounting frame 3. Then, the conversion block 6 is pulled out from the cavity 401 and moves along with the telescopic cable 5. After the conversion block 6 is pulled out, it is placed into the positioning groove 8 of the connecting seat 7 and connected to the wiring hole 801 on the inner wall of the positioning groove 8 through the connector 601, so that it is connected to the control console 1. The intermediate component in the conversion block 6 converts the data and uniformly collects and transmits it to the control console 1, avoiding data loss or errors due to incompatibility, ensuring the accuracy of data transmission, and ensuring the management and control of the monitoring equipment by the control system, thus ensuring the monitoring and control of different electromechanical equipment in the mine.

[0032] The contents not described in detail in this specification are existing technologies known to those skilled in the art.

[0033] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A safety monitoring device for mine electromechanical applications, comprising a control console (1), wherein the control console (1) is internally equipped with a conversion component for compatibility with sensor data from different monitoring devices, characterized in that: The conversion component includes multiple partitions (2) disposed inside the console (1), and each of the multiple partitions (2) is provided with a mounting frame (3) at one end, and a loading compartment (301) is provided inside the mounting frame (3). The loading compartment (301) is provided with a turntable (4) inside. The outer wall of the turntable (4) is provided with multiple cavities (401). The turntable (4) is provided with an inner shaft (402) inside. The outer wall of the inner shaft (402) is provided with multiple telescopic lines (5). The other end of the telescopic line (5) is provided with a conversion block (6). The outer wall of the conversion block (6) is provided with a connector (601). Each of the partition plates (2) is provided with a connecting seat (7) on one side. The connecting seat (7) is provided with a positioning groove (8) inside. The inner wall of the positioning groove (8) is provided with a wiring hole (801).

2. The safety monitoring device for mine electromechanical equipment according to claim 1, characterized in that: Multiple partition plates (2) are arrayed inside the console (1). The mounting frame (3) is located at one end of the partition plate (2) and is embedded and connected to the inner wall of the console (1). The loading compartment (301) is an open structure.

3. The safety monitoring device for mine electromechanical equipment according to claim 2, characterized in that: The turntable (4) is located inside the loading chamber (301) of the mounting frame (3) and is rotatably connected to the inner wall of the loading chamber (301) via a connecting shaft. Multiple cavities (401) are distributed in a ring on the outer wall of the turntable (4).

4. A safety monitoring device for mine electromechanical equipment according to claim 2, characterized in that: The inner shaft (402) is located inside the turntable (4) and is coaxially connected to the turntable (4), and communicates with multiple cavities (401). A signal receiver is provided inside the inner shaft (402). One end of each of the multiple telescopic lines (5) is connected to the inner shaft (402), and the other end is connected to the conversion block (6).

5. A safety monitoring device for mine electromechanical equipment according to claim 1, characterized in that: The connecting seat (7) is located on one side of the mounting frame (3), and the positioning groove (8) on one side of the connecting seat (7) is connected to the loading compartment (301) inside the mounting frame (3).

6. A safety monitoring device for mine electromechanical equipment according to claim 5, characterized in that: The conversion block (6) is located in the cavity (401) and is slidably connected to the inner wall of the cavity (401). The conversion block (6) can be pulled out from the cavity (401) and extended into the positioning groove (8) in the connecting seat (7), and is slidably connected to the positioning groove (8) so that the connector (601) at one end is inserted into the wiring hole (801) on the inner wall of the positioning groove (8).

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