CN111474914B - Fault code big data storage system - Google Patents

Abstract

The invention relates to a fault code big data storage system, which comprises: the emergency flameout mechanism is arranged in the firework releasing equipment and comprises signal receiving equipment, circuit disconnecting equipment and state reporting equipment, wherein the signal receiving equipment is used for receiving unmanned detection signals or manned detection signals; the big data server is used for receiving and storing fault codes of electronic elements of the firework releasing equipment through a network for subsequent searching and statistics; and the circuit breaking equipment is arranged at one end of the field firing resistor and is used for carrying out breaking operation on a circuit connected with one end of the field firing resistor when the person detection signal is received. The fault code big data storage system is safe, reliable and stable in operation. Due to the fact that the large data storage mode is adopted to backup fault codes of electronic components in the firing process of each firework releasing device, improvement and maintenance of product quality of the firework releasing devices are facilitated.

Description

Fault code big data storage system

Technical Field

The invention relates to the field of big data storage, in particular to a fault code big data storage system.

Background

To acquire the cognitive big data of the system, the system must be decomposed comprehensively and finely, and the development is carried out from three layers:

the first level is theory, which is the necessary path for cognition and is the baseline for widespread acceptance and dissemination. The overall description and qualification of the industry on the big data are understood from the characteristic definition of the big data; deeply analyzing the rarity of the big data from the discussion of the value of the big data; the development trend of big data is known; the long game between the person and the data is reviewed from this particular and important perspective of big data privacy.

The second level is technology, which is a means and advancing foundation for large data value embodiment. The whole process of big data acquisition, processing, storage and result formation is described herein from the development of cloud computing, distributed processing technology, storage technology and perception technology, respectively.

The third level is practice, which is the ultimate value embodiment of big data. The beautiful scene that the big data already shows and the blueprint to be realized are depicted from the big data of the internet, the big data of the government, the big data of the enterprise and the big data of the individual respectively.

The application of big data is very extensive, if can with big data storage application to the trouble location of each automation fireworks release equipment's concrete setting off, when promoting the fireworks safety and the reliability of setting off, can give the trouble code of each fireworks release equipment that breaks down fast, in time, provide valuable reference data for the structural improvement of relevant designer's fireworks release equipment. However, such applications do not exist in the prior art.

Disclosure of Invention

The invention at least needs to have the following three key points:

(1) constructing a targeted firing control circuit, and refusing to execute electronic ignition operation of the firework releasing equipment when a closer human body object exists around the firework releasing equipment so as to avoid accidentally injuring people nearby the firework releasing equipment;

(2) the power supply battery, the circuit disconnecting equipment, the field firing resistor and the electronic control switch form a circuit loop under the condition that the circuit disconnecting equipment and the electronic control switch are respectively communicated with circuits at two ends of the field firing resistor, so that the specific construction of a targeted firing control circuit is realized;

(3) and storing and backing up the fault codes of the electronic elements of each firework releasing device in a big data storage mode so as to facilitate subsequent fault location of the firework releasing devices and further optimize the design quality of the firework releasing devices.

According to an aspect of the present invention, there is provided a fault code big data storage system, the system including:

the emergency flameout mechanism is arranged in the firework releasing equipment and comprises signal receiving equipment, circuit disconnecting equipment and state reporting equipment, wherein the signal receiving equipment is used for receiving unmanned detection signals or manned detection signals;

the big data server is used for receiving and storing fault codes of electronic elements of the firework releasing equipment through a network for subsequent searching and statistics;

the circuit disconnecting device is arranged at one end of the on-site firing resistor, is connected with the signal receiving device, and is used for disconnecting the circuit connected with one end of the on-site firing resistor when receiving the human detection signal and connecting the circuit connected with one end of the on-site firing resistor when receiving the unmanned detection signal;

the on-site firing resistor is embedded in the gunpowder of the firework releasing equipment and used for igniting the surrounding gunpowder by heating when the power supply is switched on so as to ignite the firework releasing equipment to release the firework;

the panoramic capture device is arranged at the top of the firework releasing device and used for carrying out panoramic shooting on the periphery of the firework releasing device to obtain a panoramic capture image;

the artifact removing device is arranged at the top of the firework releasing device, connected with the panoramic snapshot device and used for executing artifact removing processing on the received panoramic snapshot image to obtain a field clear image;

the signal equalization equipment is connected with the artifact removal equipment and used for executing histogram equalization processing based on a density function on the received field cleaning image so as to obtain and output a corresponding signal equalization image;

the contour identification device is respectively connected with the signal receiving device and the signal equalization device and is used for identifying a human body object on the basis of a reference human body contour to the received signal equalization image so as to send a person detection signal when the human body object occupying the signal equalization image with the area ratio exceeding the limit is identified;

and the contour recognition equipment is also used for sending out an unmanned detection signal when recognizing that no human body object occupying the signal equalization image with the area ratio exceeding the limit exists.

The fault code big data storage system is safe, reliable and stable in operation. Due to the fact that the large data storage mode is adopted to backup fault codes of electronic components in the firing process of each firework releasing device, improvement and maintenance of product quality of the firework releasing devices are facilitated.

Drawings

Embodiments of the invention will now be described with reference to the accompanying drawings, in which:

fig. 1 is an application scenario diagram of a fault code big data storage system constructed by the invention.

Fig. 2 is a block diagram showing the structure of a fault code big data storage system according to a first example of the embodiment of the present invention.

Fig. 3 is a block diagram illustrating a structure of a fault code big data storage system according to a second example of the embodiment of the present invention.

Detailed Description

An embodiment of a fault code big data storage system of the present invention will be described in detail with reference to the accompanying drawings.

At present, all fireworks release equipment are disposable products, once the fireworks release equipment is set off, relevant set-off data cannot be collected, and particularly, set-off faults of electronic elements cause that relevant manufacturers cannot upgrade and update subsequent products; meanwhile, the existing conditions of nearby personnel are not considered in the electronically designed firework releasing equipment, and the personnel of the nearby personnel are easily injured when the firework releasing equipment is set off.

In order to overcome the defects, the invention builds a fault code big data storage system, and can effectively solve the corresponding technical problem.

Fig. 1 shows an application scenario diagram of the fault code big data storage system constructed by the invention, as shown in fig. 1, more than one firework releasing device exists, fault location of the flame releasing device is executed by a big data server in a network communication mode, and the network is composed of at least one network element including a network element a, a network element B and a network element C.

To facilitate further understanding and appreciation of the specific structure of the fault code big data storage system of the present invention, the present invention is explained below using one or more embodiments.

< first embodiment >

Fig. 2 is a block diagram showing a structure of a fault code big data storage system according to a first example of an embodiment of the present invention, the system including:

the emergency flameout mechanism is arranged in the firework releasing equipment and comprises signal receiving equipment, circuit disconnecting equipment and state reporting equipment, wherein the signal receiving equipment is used for receiving unmanned detection signals or manned detection signals;

the big data server is used for receiving and storing fault codes of electronic elements of the firework releasing equipment through a network for subsequent searching and statistics;

the circuit disconnecting device is arranged at one end of the on-site firing resistor, is connected with the signal receiving device, and is used for disconnecting the circuit connected with one end of the on-site firing resistor when receiving the human detection signal and connecting the circuit connected with one end of the on-site firing resistor when receiving the unmanned detection signal;

the on-site firing resistor is embedded in the gunpowder of the firework releasing equipment and used for igniting the surrounding gunpowder by heating when the power supply is switched on so as to ignite the firework releasing equipment to release the firework;

the panoramic capture device is arranged at the top of the firework releasing device and used for carrying out panoramic shooting on the periphery of the firework releasing device to obtain a panoramic capture image;

the artifact removing device is arranged at the top of the firework releasing device, connected with the panoramic snapshot device and used for executing artifact removing processing on the received panoramic snapshot image to obtain a field clear image;

the signal equalization equipment is connected with the artifact removal equipment and used for executing histogram equalization processing based on a density function on the received field cleaning image so as to obtain and output a corresponding signal equalization image;

the contour identification device is respectively connected with the signal receiving device and the signal equalization device and is used for identifying a human body object on the basis of a reference human body contour to the received signal equalization image so as to send a person detection signal when the human body object occupying the signal equalization image with the area ratio exceeding the limit is identified;

and the contour recognition equipment is also used for sending out an unmanned detection signal when recognizing that no human body object occupying the signal equalization image with the area ratio exceeding the limit exists.

Fig. 3 is a block diagram showing a structure of a fault code big data storage system according to a second example of the embodiment of the present invention, the system including:

the power supply battery is arranged in the firework releasing equipment and is arranged on the left side of the on-site firing resistor;

the electronic control switch is used for communicating a circuit at the other end of the field firing resistor when receiving an electronic ignition instruction;

the emergency flameout mechanism is arranged in the firework releasing equipment and comprises signal receiving equipment, circuit disconnecting equipment and state reporting equipment, wherein the signal receiving equipment is used for receiving unmanned detection signals or manned detection signals;

the big data server is used for receiving and storing fault codes of electronic elements of the firework releasing equipment through a network for subsequent searching and statistics;

the circuit disconnecting device is arranged at one end of the on-site firing resistor, is connected with the signal receiving device, and is used for disconnecting the circuit connected with one end of the on-site firing resistor when receiving the human detection signal and connecting the circuit connected with one end of the on-site firing resistor when receiving the unmanned detection signal;

the on-site firing resistor is embedded in the gunpowder of the firework releasing equipment and used for igniting the surrounding gunpowder by heating when the power supply is switched on so as to ignite the firework releasing equipment to release the firework;

the panoramic capture device is arranged at the top of the firework releasing device and used for carrying out panoramic shooting on the periphery of the firework releasing device to obtain a panoramic capture image;

the artifact removing device is arranged at the top of the firework releasing device, connected with the panoramic snapshot device and used for executing artifact removing processing on the received panoramic snapshot image to obtain a field clear image;

the signal equalization equipment is connected with the artifact removal equipment and used for executing histogram equalization processing based on a density function on the received field cleaning image so as to obtain and output a corresponding signal equalization image;

the contour identification device is respectively connected with the signal receiving device and the signal equalization device and is used for identifying a human body object on the basis of a reference human body contour to the received signal equalization image so as to send a person detection signal when the human body object occupying the signal equalization image with the area ratio exceeding the limit is identified;

and the contour recognition equipment is also used for sending out an unmanned detection signal when recognizing that no human body object occupying the signal equalization image with the area ratio exceeding the limit exists.

Next, a detailed description of the structure of the fault code large data storage system according to the embodiments of the present invention will be further described.

In the fault code big data storage system:

the power supply battery, the circuit breaking equipment, the field firing resistor and the electronic control switch are sequentially arranged;

the power supply battery, the circuit disconnecting device, the field firing resistor and the electronic control switch form a circuit loop under the condition that the circuit disconnecting device and the electronic control switch are respectively communicated with circuits at two ends of the field firing resistor;

wherein the power supply battery, the circuit breaking device, the field firing resistor and the electronic control switch break the circuit loop when the circuit breaking device or the electronic control switch breaks one end of the lines at both ends of the field firing resistor.

In the fault code big data storage system, the system further comprises:

and the time division duplex communication equipment is respectively connected with the artifact removing equipment and the signal equalizing equipment, is also connected with the big data server through a network, and is used for receiving and wirelessly reporting various fault codes of the artifact removing equipment or the signal equalizing equipment.

In the fault code big data storage system:

the device for removing the artifacts is internally provided with a first fault self-checking unit which is used for carrying out self-checking on internal faults of the device for removing the artifacts and sending fault codes.

In the fault code big data storage system:

and a second fault self-checking unit is arranged in the signal equalization equipment and is used for carrying out self-checking on internal faults of the signal equalization equipment and sending fault codes.

In the fault code big data storage system:

the first fault self-checking unit and the second fault self-checking unit are respectively realized by editable logic devices with different models.

In the fault code big data storage system:

the artifact removing device is also internally provided with a first electric quantity measuring unit used for measuring the current residual electric quantity of the artifact removing device.

In the fault code big data storage system:

the signal equalization equipment is also internally provided with a second electric quantity measuring unit used for measuring the current residual electric quantity of the signal equalization equipment.

In the fault code big data storage system:

the first electric quantity measuring unit and the second electric quantity measuring unit share the same quartz oscillation device.

In addition, time division duplexing is a duplexing method of a communication system for separating reception and transmission channels in a mobile communication system. Mobile communication is currently developing to the third generation, and china filed the third generation draft of mobile communication standards (TD-SCDMA) in 6 months 1997, and its features such as TDD mode and new technology of smart antenna are highly evaluated and become one of three main candidate standards. TDD mode has not been emphasized on the whole in FDD mode in first and second generation mobile communication systems. However, due to the need for new services and the development of new technologies, and many advantages of the TDD mode, the TDD mode will be increasingly emphasized.

The working principle of time division duplex is as follows: TDD is a duplex scheme of a communication system for separating a reception channel and a transmission channel (or uplink and downlink) in a mobile communication system. In the TDD mode mobile communication system, the receiving and transmitting are in different time slots of the same frequency channel, namely carrier, and the receiving and transmitting channels are separated by using the guaranteed time; in the FDD mode, the receiving and transmitting are performed on two separate symmetric frequency channels, and the receiving and transmitting channels are separated by a guaranteed frequency band.

The characteristics and communication benefits of mobile communication systems employing different duplex modes are different. The uplink and downlink channels in the TDD mode mobile communication system use the same frequency, and thus have reciprocity of the uplink and downlink channels, which brings many advantages to the TDD mode mobile communication system.

In TDD mode, the transmission of information in uplink and downlink can be performed on the same carrier frequency, i.e. the transmission of information in uplink and the transmission of information in downlink are realized by time division on the same carrier.

It is to be understood that while the present invention has been described in conjunction with the preferred embodiments thereof, it is not intended to limit the invention to those embodiments. It will be apparent to those skilled in the art from this disclosure that many changes and modifications can be made, or equivalents modified, in the embodiments of the invention without departing from the scope of the invention. Therefore, any simple modification, equivalent change and modification made to the above embodiments according to the technical essence of the present invention are still within the scope of the protection of the technical solution of the present invention, unless the contents of the technical solution of the present invention are departed.

Claims (9)

1. A fault code big data storage system, comprising:

the emergency flameout mechanism is arranged in the firework releasing equipment and comprises signal receiving equipment, circuit disconnecting equipment and state reporting equipment, wherein the signal receiving equipment is used for receiving unmanned detection signals or manned detection signals;

the big data server is used for receiving and storing fault codes of electronic elements of the firework releasing equipment through a network for subsequent searching and statistics;

the circuit disconnecting device is arranged at one end of the on-site firing resistor, is connected with the signal receiving device, and is used for disconnecting the circuit connected with one end of the on-site firing resistor when receiving the human detection signal and connecting the circuit connected with one end of the on-site firing resistor when receiving the unmanned detection signal;

the on-site firing resistor is embedded in the gunpowder of the firework releasing equipment and used for igniting the surrounding gunpowder by heating when the power supply is switched on so as to ignite the firework releasing equipment to release the firework;

the panoramic capture device is arranged at the top of the firework releasing device and used for carrying out panoramic shooting on the periphery of the firework releasing device to obtain a panoramic capture image;

the artifact removing device is arranged at the top of the firework releasing device, connected with the panoramic snapshot device and used for executing artifact removing processing on the received panoramic snapshot image to obtain a field clear image;

the signal equalization equipment is connected with the artifact removal equipment and used for executing histogram equalization processing based on a density function on the received field cleaning image so as to obtain and output a corresponding signal equalization image;

the contour identification device is respectively connected with the signal receiving device and the signal equalization device and is used for identifying a human body object on the basis of a reference human body contour to the received signal equalization image so as to send a person detection signal when the human body object occupying the signal equalization image with the area ratio exceeding the limit is identified;

the contour recognition equipment is further used for sending out an unmanned detection signal when no human body object occupying the signal equalization image with the area ratio exceeding the limit is recognized;

the power supply battery is arranged in the firework releasing equipment and is arranged on the left side of the on-site firing resistor;

and the electronic control switch is used for communicating a circuit at the other end of the field firing resistor when receiving an electronic ignition instruction.

2. The fault code big data storage system according to claim 1, wherein:

the power supply battery, the circuit breaking equipment, the field firing resistor and the electronic control switch are sequentially arranged;

the power supply battery, the circuit disconnecting device, the field firing resistor and the electronic control switch form a circuit loop under the condition that the circuit disconnecting device and the electronic control switch are respectively communicated with circuits at two ends of the field firing resistor;

wherein the power supply battery, the circuit breaking device, the field firing resistor and the electronic control switch break the circuit loop when the circuit breaking device or the electronic control switch breaks one end of the lines at both ends of the field firing resistor.

3. The fault code big data storage system of claim 2, wherein the system further comprises:

and the time division duplex communication equipment is respectively connected with the artifact removing equipment and the signal equalizing equipment, is also connected with the big data server through a network, and is used for receiving and wirelessly reporting various fault codes of the artifact removing equipment or the signal equalizing equipment.

4. The fault code big data storage system according to claim 3, wherein:

the device for removing the artifacts is internally provided with a first fault self-checking unit which is used for carrying out self-checking on internal faults of the device for removing the artifacts and sending fault codes.

5. The fault code big data storage system according to claim 4, wherein:

and a second fault self-checking unit is arranged in the signal equalization equipment and is used for carrying out self-checking on internal faults of the signal equalization equipment and sending fault codes.

6. The fault code big data storage system according to claim 5, wherein:

the first fault self-checking unit and the second fault self-checking unit are respectively realized by editable logic devices with different models.

7. The fault code big data storage system according to claim 6, wherein:

the artifact removing device is also internally provided with a first electric quantity measuring unit used for measuring the current residual electric quantity of the artifact removing device.

8. The fault code big data storage system according to claim 7, wherein:

the signal equalization equipment is also internally provided with a second electric quantity measuring unit used for measuring the current residual electric quantity of the signal equalization equipment.

9. The fault code big data storage system according to claim 8, wherein:

the first electric quantity measuring unit and the second electric quantity measuring unit share the same quartz oscillation device.

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