CN113301691A - Stage intelligence lamps and lanterns control system - Google Patents

Abstract

The invention discloses an intelligent stage lamp control system which comprises a CPU, a man-machine interaction module, an OP, a function key, a CEM, a dimming module, a temperature sensing module, a heat dissipation control module, a feedback monitoring module and a filament preheating module, wherein the CPU is used for processing, operating and executing various instructions of the whole intelligent stage lamp control system; the invention can facilitate people to know the main working state in time, has comprehensive monitoring and timely feedback, is beneficial to improving and adjusting the working state of the system aiming at the monitoring condition, is more beneficial to use, can effectively avoid the phenomenon that the lamp filament is burnt off due to large current when being suddenly lightened, avoids damaging the lamp, reduces the material consumption on one hand, and avoids influencing the performance effects of singing, dancing, action demonstration and the like on the other hand.

Description

Stage intelligence lamps and lanterns control system

Technical Field

The invention relates to the field of lamp control systems, in particular to an intelligent stage lamp control system.

Background

The stage is a place for providing singing, dancing and action demonstration for people, and various lamps are needed to be matched in work, so that the performance effects of singing, dancing, action demonstration and the like of people are improved, and the work of all the lamps is controlled by a background system, so that an intelligent stage lamp control system is needed.

The existing stage intelligent lamp control system has certain disadvantages to be improved when in use, and firstly, the existing stage intelligent lamp control system cannot monitor each working state, so that people cannot know the main working state in the system in time, and the system is not beneficial to operation, control and improvement of the system and is not beneficial to use; secondly, current stage intelligence lamps and lanterns control system does not possess the function of preheating to the filament, and before each lamps and lanterns did not light, the temperature is low, so the resistance is just very little, if the filament does not in time preheat, when lighting suddenly, the electric current will be very big, just this moment burns out the filament easily, will cause lamps and lanterns to damage, leads to the consumptive material serious on the one hand, and on the other hand also influences the performance effects such as singing, dancing, action demonstration.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the existing stage intelligent lamp control system cannot monitor each working state, so that people cannot know the main working state in the system in time, and the system is not beneficial to operation, control and improvement of the system and use; secondly, current stage intelligence lamps and lanterns control system does not possess the function of preheating to the filament, and before each lamps and lanterns did not light, the temperature is low, so the resistance is just very little, if the filament does not in time preheat, when lighting suddenly, the electric current will be very big, just this moment burns out the filament easily, will cause lamps and lanterns to damage, leads to the consumptive material serious on the one hand, and on the other hand also influences the performance effects such as singing, dancing, action demonstration.

The invention solves the technical problems through the following technical scheme, and the stage intelligent lamp control system comprises a CPU, a human-computer interaction module, an OP, a function key, a CEM, a dimming module, a temperature induction module, a heat dissipation control module, a feedback monitoring module and a filament preheating module;

the CPU is used for processing, calculating and executing various instructions of the whole stage intelligent lamp control system;

the human-computer interaction module is used for realizing a human-computer interaction function;

the OP (touch screen) and the function keys are used for displaying and cooperating with the man-machine interaction module to control the lamp control system;

the dimming module is used for executing a dimming command;

the CEM (double control module) is used for controlling the dimming module to work;

the temperature sensing module is used for monitoring the system temperature in real time;

the heat dissipation control module is used for being matched with the temperature sensing module to dissipate heat of the system;

the feedback monitoring module is used for monitoring various working states of the system and feeding back the working states in time;

the filament preheating module is used for preheating the filament.

Preferably, the feedback monitoring module comprises a voltage acquisition unit, a loop power acquisition unit, a loop output current acquisition unit, a contact acquisition unit, a temperature sensor, a wind speed monitoring unit, a recording unit, a feedback unit, a storage unit, a communication unit and a display unit.

Preferably, the feedback monitoring module specifically comprises the following processing steps:

the method comprises the following steps: the system comprises a voltage acquisition unit, a loop power supply sampling unit, a loop output current acquisition unit, a contact acquisition unit, a temperature sensor and a wind speed monitoring unit, wherein the voltage acquisition unit acquires working voltage in real time, the loop power supply sampling unit acquires the working state of each loop, the loop output current acquisition unit acquires the output current of each loop, the contact acquisition unit acquires the on-off state, the temperature sensor acquires the working temperature, and the wind speed monitoring unit acquires the working state of a fan;

step two: the collected working voltage, the working state of each loop, the output current of each loop, the switching state, the working temperature and the working state of the fan are recorded in the storage unit by the recording unit;

step three: meanwhile, the recording unit transmits all the acquired information to the feedback unit, the feedback unit transmits the information to an external communication terminal through the communication unit on one hand, and the feedback unit displays the information on the display terminal through the display unit on the other hand.

Preferably, the storage unit comprises a plurality of partition units, each partition unit is named as a-area unit, a b-area unit and a c-area unit, wherein each partition unit stores collected data information.

Preferably, the filament preheating module includes an RTC, a timing unit, a processing unit, a control unit, and a preheating circuit.

Preferably, the filament preheating module comprises the following specific processing steps:

step 1: acquiring the current network time in real time through an RTC (real time clock);

step 2: setting preheating time by using a timing module;

and step 3: when the time acquired by the RTC is the same as the time set by the timing module, the processing unit processes the information and transmits the processed information to the control unit;

and 4, step 4: the control unit controls the preheating circuit to work, and the preheating circuit realizes the preheating of the lamp filament through the current between the lamp filament and the starting capacitor.

Preferably, the timing unit comprises a timing starting unit and a timing working unit, the timing starting unit is used for setting the starting time of the filament preheating module, the timing working unit is used for setting the working time of the filament preheating module, and the working time is 5-10 s.

Preferably, the stage intelligent lamp control system comprises the following specific processing steps when in use:

s1: a working command is issued through a functional key or an OP (operation top) in cooperation with a human-computer interaction module;

s2: the CPU processes and operates after receiving the command, and then executes the work of the feedback monitoring module, the filament preheating module, the CEM and the temperature sensing module;

s3: the CEM controls the dimming module to work after obtaining the command, and controls the lamp to work;

s4: the heat dissipation control module adjusts the working speed according to the temperature fed back by the temperature sensing module, and the higher the temperature is, the faster the rotating speed is, and otherwise, the rotating speed is lower.

Compared with the prior art, the invention has the following advantages:

by arranging the feedback monitoring module, the working voltage, the working state of each loop, the output current of each loop, the switching state, the working temperature and the working state of the fan can be monitored in real time, and are recorded in the storage unit by the recording unit, and meanwhile, the recording unit transmits all the acquired information to the feedback unit;

preheating module through setting up the filament, through the set time, the time that obtains when RTC is the same with the time of timing module setting, processing unit transmits to the control unit after with information processing, control unit control preheating circuit work, preheating circuit passes through the filament and starts the electric current between the electric capacity and realize the filament and preheat, can effectually avoid, when lighting suddenly, the electric current is very big, the phenomenon of burning out the filament, avoid causing lamps and lanterns to damage, reduce the consumptive material on the one hand, on the other hand also avoids influencing singing, dancing, expression effects such as action demonstration.

Drawings

FIG. 1 is a system block diagram of the present invention;

FIG. 2 is a system diagram of the feedback monitoring module of the present invention;

FIG. 3 is a system diagram of the filament preheating module of the present invention;

fig. 4 is a circuit diagram of the preheat circuit of the present invention.

Detailed Description

The following examples are given for the detailed implementation and specific operation of the present invention, but the scope of the present invention is not limited to the following examples.

As shown in fig. 1 to 4, the present embodiment provides a technical solution: an intelligent stage lamp control system comprises a CPU, a human-computer interaction module, an OP, a function key, a CEM, a dimming module, a temperature sensing module, a heat dissipation control module, a feedback monitoring module and a filament preheating module;

the CPU is used for processing, calculating and executing various instructions of the whole stage intelligent lamp control system;

the human-computer interaction module is used for realizing a human-computer interaction function;

the OP (touch screen) and the function keys are used for displaying and cooperating with the man-machine interaction module to control the lamp control system;

the dimming module is used for executing a dimming command;

the CEM (double control module) is used for controlling the dimming module to work;

the temperature sensing module is used for monitoring the system temperature in real time;

the heat dissipation control module is used for being matched with the temperature sensing module to dissipate heat of the system;

the feedback monitoring module is used for monitoring various working states of the system and feeding back the working states in time;

the filament preheating module is used for preheating the filament.

The feedback monitoring module comprises a voltage acquisition unit, a loop power acquisition unit, a loop output current acquisition unit, a contact acquisition unit, a temperature sensor, a wind speed monitoring unit, a recording unit, a feedback unit, a storage unit, a communication unit and a display unit.

The feedback monitoring module comprises the following specific processing steps:

the method comprises the following steps: the system comprises a voltage acquisition unit, a loop power supply sampling unit, a loop output current acquisition unit, a contact acquisition unit, a temperature sensor and a wind speed monitoring unit, wherein the voltage acquisition unit acquires working voltage in real time, the loop power supply sampling unit acquires the working state of each loop, the loop output current acquisition unit acquires the output current of each loop, the contact acquisition unit acquires the on-off state, the temperature sensor acquires the working temperature, and the wind speed monitoring unit acquires the working state of a fan;

step two: the collected working voltage, the working state of each loop, the output current of each loop, the switching state, the working temperature and the working state of the fan are recorded in the storage unit by the recording unit;

step three: meanwhile, the recording unit transmits all the acquired information to the feedback unit, the feedback unit transmits the information to an external communication terminal through the communication unit on one hand, and the feedback unit displays the information on the display terminal through the display unit on the other hand.

The storage unit comprises a plurality of partition units, each partition unit is named as a partition unit a, a partition unit b and a partition unit c, wherein each partition unit stores collected data information.

The filament preheating module comprises an RTC, a timing unit, a processing unit, a control unit and a preheating circuit.

The filament preheating module comprises the following specific processing steps:

step 1: acquiring the current network time in real time through an RTC (real time clock);

step 2: setting preheating time by using a timing module;

and step 3: when the time acquired by the RTC is the same as the time set by the timing module, the processing unit processes the information and transmits the processed information to the control unit;

and 4, step 4: the control unit controls the preheating circuit to work, and the preheating circuit realizes the preheating of the lamp filament through the current between the lamp filament and the starting capacitor.

The timing unit comprises a timing starting unit and a timing working unit, the timing starting unit is used for setting the starting time of the filament preheating module, the timing working unit is used for setting the working time of the filament preheating module, and the working time is 5-10 s.

The stage intelligent lamp control system comprises the following specific processing steps when in use:

s1: a working command is issued through a functional key or an OP (operation top) in cooperation with a human-computer interaction module;

s2: the CPU processes and operates after receiving the command, and then executes the work of the feedback monitoring module, the filament preheating module, the CEM and the temperature sensing module;

s3: the CEM controls the dimming module to work after obtaining the command, and controls the lamp to work;

s4: the heat dissipation control module adjusts the working speed according to the temperature fed back by the temperature sensing module, and the higher the temperature is, the faster the rotating speed is, and otherwise, the rotating speed is lower.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (8)

1. An intelligent stage lamp control system is characterized by comprising a CPU, a man-machine interaction module, an OP, a function key, a CEM, a dimming module, a temperature induction module, a heat dissipation control module, a feedback monitoring module and a filament preheating module;

the CPU is used for processing, calculating and executing various instructions of the whole stage intelligent lamp control system;

the human-computer interaction module is used for realizing a human-computer interaction function;

the OP (touch screen) and the function keys are used for displaying and cooperating with the man-machine interaction module to control the lamp control system;

the dimming module is used for executing a dimming command;

the CEM (double control module) is used for controlling the dimming module to work;

the temperature sensing module is used for monitoring the system temperature in real time;

the heat dissipation control module is used for being matched with the temperature sensing module to dissipate heat of the system;

the feedback monitoring module is used for monitoring various working states of the system and feeding back the working states in time;

the filament preheating module is used for preheating the filament.

2. A stage intelligent light control system according to claim 1, wherein: the feedback monitoring module comprises a voltage acquisition unit, a loop power acquisition unit, a loop output current acquisition unit, a contact acquisition unit, a temperature sensor, a wind speed monitoring unit, a recording unit, a feedback unit, a storage unit, a communication unit and a display unit.

3. A stage intelligent light control system according to claim 2, wherein: the feedback monitoring module comprises the following specific processing steps:

the method comprises the following steps: the system comprises a voltage acquisition unit, a loop power supply sampling unit, a loop output current acquisition unit, a contact acquisition unit, a temperature sensor and a wind speed monitoring unit, wherein the voltage acquisition unit acquires working voltage in real time, the loop power supply sampling unit acquires the working state of each loop, the loop output current acquisition unit acquires the output current of each loop, the contact acquisition unit acquires the on-off state, the temperature sensor acquires the working temperature, and the wind speed monitoring unit acquires the working state of a fan;

step two: the collected working voltage, the working state of each loop, the output current of each loop, the switching state, the working temperature and the working state of the fan are recorded in the storage unit by the recording unit;

step three: meanwhile, the recording unit transmits all the acquired information to the feedback unit, the feedback unit transmits the information to an external communication terminal through the communication unit on one hand, and the feedback unit displays the information on the display terminal through the display unit on the other hand.

4. A stage intelligent light control system according to claim 3, wherein: the storage unit comprises a plurality of partition units, each partition unit is named as a partition unit a, a partition unit b and a partition unit c, and each partition unit stores collected data information.

5. A stage intelligent light control system according to claim 1, wherein: the filament preheating module comprises an RTC, a timing unit, a processing unit, a control unit and a preheating circuit.

6. A stage intelligent light control system according to claim 4, wherein: the filament preheating module comprises the following specific processing steps:

step 1: acquiring the current network time in real time through an RTC (real time clock);

step 2: setting preheating time by using a timing module;

and step 3: when the time acquired by the RTC is the same as the time set by the timing module, the processing unit processes the information and transmits the processed information to the control unit;

and 4, step 4: the control unit controls the preheating circuit to work, and the preheating circuit realizes the preheating of the lamp filament through the current between the lamp filament and the starting capacitor.

7. A stage intelligent light control system according to claim 6, wherein: the timing unit comprises a timing starting unit and a timing working unit, the timing starting unit is used for setting the starting time of the filament preheating module, the timing working unit is used for setting the working time of the filament preheating module, and the working time is 5-10 s.

8. A stage intelligent lighting control system according to any one of claims 1-7, wherein: the stage intelligent lamp control system comprises the following specific processing steps when in use:

s1: a working command is issued through a functional key or an OP (operation top) in cooperation with a human-computer interaction module;

s2: the CPU processes and operates after receiving the command, and then executes the work of the feedback monitoring module, the filament preheating module, the CEM and the temperature sensing module;

s3: the CEM controls the dimming module to work after obtaining the command, and controls the lamp to work;

s4: the heat dissipation control module adjusts the working speed according to the temperature fed back by the temperature sensing module, and the higher the temperature is, the faster the rotating speed is, and otherwise, the rotating speed is lower.

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