CN214851858U - Intelligent heat preservation lamp control system - Google Patents

Abstract

The utility model discloses an intelligence heat preservation lamp control system. The system comprises: the intelligent heat preservation system comprises an intelligent control terminal, a temperature sensor, an intelligent heat preservation lamp, a management terminal and a server; the intelligent control terminal and the management terminal both comprise Bluetooth modules; the temperature sensor is connected with the intelligent control terminal, the intelligent control terminal is electrically connected with the intelligent heat preservation lamp, the intelligent control terminal is connected with the management terminal through the Bluetooth module, the management terminal is further connected with the server, the server is used for storing the monitoring data in a backup mode, and a second control instruction is generated according to the operation of the WEB end and/or the mobile terminal connected with the WEB end. Through the integrated design of intelligent control ware and intelligent heat preservation lamp to and use bluetooth module and management terminal, server and mobile terminal to carry out data communication in the intelligent control ware, realize intelligent control, convenient data transmission, reduction wiring and reduction personnel cost of intelligent heat preservation lamp, realize remote management and reduce the effect that the germ is brought into the risk of aquaculture factory.

Description

Intelligent heat preservation lamp control system

Technical Field

The embodiment of the utility model provides a relate to heat preservation control technology, especially relate to an intelligence heat preservation lamp control system.

Background

The heat preservation lamp and the heat preservation plate are widely applied to the field of livestock heat preservation. With the development of the scale, informatization and intellectualization of the breeding industry, the traditional whole-house constant-temperature control temperature regulation system cannot meet the breeding requirements.

The traditional heat preservation lamp only has two grades of power, and the temperature adjusting mode is that the height is adjusted by depending on mechanical parts, so that the accurate control of heating/heat preservation temperature cannot be met, the waste of electric energy is serious, and the service life of the heat preservation lamp is shortened; the heat preservation lamp can not be networked, and can only rely on manual site monitoring and judgment, so that the manual management cost is increased, meanwhile, pathogenic bacteria infected cubs can be brought in due to the fact that workers enter the heat preservation lamp, and temperature data cannot be effectively stored.

SUMMERY OF THE UTILITY MODEL

The utility model provides an intelligence heat preservation lamp control system to realize intelligent control and the remote management of intelligence heat preservation lamp, reduce the wiring and reduce personnel's cost and reduce the effect that the germ was brought into the risk of aquaculture.

To achieve the purpose, the utility model adopts the following technical proposal:

an intelligent heat-preservation lamp control system comprises a plurality of control subsystems and a server; the control subsystem includes: the intelligent heat preservation system comprises an intelligent control terminal, a temperature sensor, an intelligent heat preservation lamp and a management terminal; the intelligent control terminal and the management terminal both comprise Bluetooth modules;

the temperature sensor is connected with the intelligent control terminal and used for monitoring the ambient temperature in real time and transmitting monitoring data to the intelligent control terminal;

the intelligent control terminal is electrically connected with the intelligent heat-preservation lamp, is connected with the management terminal through a Bluetooth module, and is used for transmitting the received monitoring data to the management terminal for storage, and generating a first control instruction corresponding to the monitoring data according to calculation of a calculation model, and/or generating a corresponding first control instruction according to a second control instruction transmitted by the management terminal, and the intelligent control terminal adjusts the working power of the intelligent heat-preservation lamp according to the first control instruction;

the management terminals of the control subsystems are connected and wirelessly networked through the Bluetooth modules, are used for data interaction, and generate a second control instruction according to the operation of the mobile terminal connected with the management terminals; the management terminal is also connected with the server and used for uploading the received monitoring data to the server and receiving a second control instruction of the server;

and the server is used for backing up and storing the monitoring data and generating the second control instruction according to the operation of the WEB end and/or the mobile terminal connected with the WEB end.

Optionally, the server is further configured to generate user management information according to input of a user at the WEB end and/or the mobile terminal, and transmit the user management information to the management terminal;

the management terminal also comprises an input device which is used for receiving the operation of the user and correspondingly generating the user management information.

Optionally, the calculation model includes an ambient temperature control curve model and a set ambient temperature value.

Optionally, the intelligent control terminal, the temperature sensor and the intelligent heat preservation lamp all include a plurality of ones; each intelligent heat preservation lamp is connected with at least one temperature sensor and one intelligent control terminal.

Optionally, the intelligent control terminal further includes a monitoring chip, configured to obtain working state information of each intelligent heat preservation lamp and upload the working state information to the management terminal; and the intelligent control terminal is also used for acquiring and storing the user management information from the management terminal.

Optionally, the intelligent control terminal is further configured to generate an alarm instruction according to the monitoring data and the working state, and transmit the alarm instruction to the management terminal.

Optionally, the management terminal further includes a display module, configured to display the monitoring data, the working state information, the user management information, and alarm information corresponding to the alarm instruction; and the alarm information is also transmitted to the server.

Optionally, the intelligent control terminal further includes at least one status indicator light and an alarm; the indicator light is used for displaying the working state information of the intelligent heat preservation light; the alarm is used for carrying out alarm prompt.

Optionally, the intelligent control terminal includes a silicon controlled voltage regulating circuit, and is configured to adjust the working voltage of the intelligent heat preservation lamp according to the first control instruction, so as to adjust the working power of the intelligent heat preservation lamp.

Optionally, the intelligent heat preservation lamp comprises an intelligent heat preservation lamp body, a waterproof connector, a connecting wire, a switch and a power plug;

the waterproof connector is connected with the intelligent heat preservation lamp main body and the connecting wire, the power plug is connected with an external power supply, and the switch is used for manually opening and closing the intelligent heat preservation lamp.

The utility model discloses an integrated design of intelligent control ware and intelligent heat preservation lamp, and use bluetooth module and management terminal in the intelligent control ware, server and mobile terminal carry out data communication, it is difficult to accurate control to solve heat preservation lamp temperature, extravagant electric energy, the data record of heat preservation lamp and environment and the higher problem of cost of labor and equipment wiring cost that transmission leads to, realize the intelligent control of intelligent heat preservation lamp, convenient data transmission, reduce the wiring and reduce personnel's cost, realize remote management and reduce the effect that the germ was brought into the risk of aquaculture.

Drawings

Fig. 1A is a schematic structural diagram of an intelligent heat-preservation lamp control subsystem provided in an embodiment of the present invention;

FIG. 1B is a schematic structural diagram of an intelligent heat-preserving lamp control system according to an embodiment of the present invention,

fig. 2 is a schematic structural diagram of another intelligent heat-preservation lamp control subsystem provided by the embodiment of the present invention;

fig. 3 is a schematic structural view of an intelligent heat preservation lamp provided by the embodiment of the utility model.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

Examples

Fig. 1A is a schematic structural view of an intelligent heat-preservation lamp control subsystem provided in an embodiment of the present invention, fig. 1B is a schematic structural view of an intelligent heat-preservation lamp control system provided in an embodiment of the present invention, and fig. 2 is a schematic structural view of another intelligent heat-preservation lamp control subsystem provided in an embodiment of the present invention; fig. 3 is a schematic structural view of an intelligent heat preservation lamp provided by the embodiment of the utility model.

As shown in fig. 1A, an intelligent heat-preservation lamp control system includes a plurality of control subsystems 10 and a server 20; the control subsystem 10 includes: the intelligent control system comprises an intelligent control terminal 100, a temperature sensor 200, an intelligent heat preservation lamp 300 and a management terminal 400; the intelligent control terminal 100 and the management terminal 400 each include a bluetooth module 500;

the temperature sensor 200 is connected to the intelligent control terminal 100, and is configured to monitor the ambient temperature in real time and transmit monitoring data to the intelligent control terminal 100;

the intelligent control terminal 100 is electrically connected with the intelligent heat preservation lamp 300, the intelligent control terminal 100 is connected with the management terminal 400 through a Bluetooth module 500, and is used for transmitting the received monitoring data to the management terminal 400 for storage, generating a first control instruction corresponding to the monitoring data according to calculation model calculation, and/or generating a corresponding first control instruction according to a second control instruction transmitted by the management terminal 400, and the intelligent control terminal 100 adjusts the working power of the intelligent heat preservation lamp 300 according to the first control instruction.

As shown in fig. 1B, the management terminals 400 of the plurality of control subsystems 10 are connected and wirelessly networked through the bluetooth module 500 for data interaction, and generate a second control instruction according to the operation of the mobile terminal connected thereto; the management terminal 400 is further connected to the server 20, and is configured to upload the received monitoring data to the server 20 and receive a second control instruction of the server 20;

the server 20 is configured to backup and store the monitoring data, and generate the second control instruction according to an operation of the WEB end and/or the mobile terminal 30 connected thereto.

In animal husbandry, the heat-preservation lamp is often used in a pigsty of a pasture to regulate the ambient temperature of piglets and sows to be born so as to be at the most favorable ambient temperature for growth and production. The intelligent heat-preservation lamp control system provided by the embodiment comprises a plurality of control subsystems 10 and a server 20, wherein each control subsystem 10 controls one or more intelligent heat-preservation lamps 300 of a pigsty; a plurality of intelligent heat preservation lamps 300 are distributed in the pigsty, a temperature sensor 200 is arranged at intervals of a preset distance to monitor the ambient temperature in the pigsty in real time, and each intelligent heat preservation lamp 300 is provided with at least one high-precision temperature sensor 200 exemplarily. Intelligent control terminal 100 and management terminal 400 all include bluetooth module 500, and intelligent control terminal 100 transmits the monitoring data of ambient temperature to management terminal 400 through bluetooth module 500, and management terminal 400 preserves data, realizes data transmission through wireless mode, can remove the trouble of networking wiring from. The intelligent control terminal 100 comprises an intelligent operation processor for storing a calculation model, and the intelligent control terminal 100 inputs the received monitoring data into the calculation model to calculate and generate a corresponding first control instruction, so that the intelligent heat preservation lamp 300 is automatically adjusted in power. Optionally, the calculation model includes an ambient temperature control curve model and a set ambient temperature value; the environment temperature control curve model is constructed according to different growth stages of the piglets and the optimal growth environment temperature, and the set environment temperature value is manually set by a user. Optionally, the intelligent control terminal 100 includes a silicon controlled voltage regulator circuit, and is configured to adjust the working voltage of the intelligent heat preservation lamp 300 according to the first control instruction, so as to adjust the working power of the intelligent heat preservation lamp. The automatic control of the required environmental temperature of the piglets in different growth stages is realized through the calculation model, the problems of frequent switching of the heat preservation lamp and frequent adjustment of the height of the heat preservation lamp by manpower are avoided, the heat preservation lamp is prevented from being in a full-power working state for a long time through power adjustment, the service life of the heat preservation lamp is prolonged, and the labor cost, the height adjustment mechanical part cost and the electric energy consumption are reduced.

Besides intelligent control, the intelligent heat preservation lamp can realize personalized adjustment according to the operation of a user; the management terminal 400 is further connected with the server 20, the input end of the server comprises a WEB end and/or a mobile terminal 30 connected with the WEB end, the monitoring data received by the server and transmitted by the management terminal 400 are backed up and stored, a user knows the current temperature of the pigsty through the monitoring data and operates through the WEB end and the mobile terminal 30 to generate a second control instruction, the management terminal 400 receives the second control instruction and generates a corresponding first control instruction to be transmitted to the intelligent control terminal 100, and the intelligent control terminal 100 adjusts the power of the intelligent heat preservation lamp 300 according to the user operation. Make the user can long-rangely monitor the ambient temperature of pig house through the APP on the handheld mobile terminal, the intelligence heat preservation lamp of right control and management. Further, as shown in fig. 1B, the management terminals 400 of the plurality of control subsystems 10 are connected via the bluetooth module 500 and are connected via a wireless network to form the intelligent heat-preservation lamp control system 1, which is used for data interaction between the plurality of management terminals 400, and is further used for generating a second control instruction according to a user operation of the mobile terminal 30 connected to any management terminal 400 in the network, and generating a corresponding first control instruction according to the second control instruction and transmitting the corresponding first control instruction to the intelligent control terminal 100 to control the intelligent heat-preservation lamp 300. When the management terminals 400 of the multiple control subsystems 10 are successfully wirelessly networked, the mobile terminals 30 are automatically searched and connected, and when the mobile terminal 30 held by a user is connected to any management terminal 400, other management terminals 400 in the group network can be operated, so that the intelligent heat preservation lamps 300 in the multiple subsystems 10 are controlled. Can remove the manual work from and get into the pig farm and carry out temperature management, practice thrift manual management cost, reduce the number of times that personnel got into the pig farm, avoid personnel to carry the influence that the germ got into the pig farm and to the porkling, improve porkling growth's security, reduce the germ and be brought into the sick hidden danger that the porkling brought in the pig farm.

The utility model discloses an integrated design of intelligent control ware and intelligent heat preservation lamp, and use bluetooth module and management terminal in the intelligent control ware, server and mobile terminal carry out data communication, it is difficult to accurate control to solve heat preservation lamp temperature, extravagant electric energy, the data record of heat preservation lamp and environment and the higher problem of cost of labor and equipment wiring cost that transmission leads to, realize the intelligent control of intelligent heat preservation lamp, convenient data transmission, reduce the wiring and reduce personnel's cost, realize remote management and reduce the effect that the germ was brought into the risk of aquaculture.

On the basis of the foregoing embodiment, optionally, the server 20 is further configured to generate user management information according to an input of a user at the WEB end and/or the mobile terminal 30, and transmit the user management information to the management terminal 400; the management terminal 400 further includes an input device 410 for receiving user operations and generating user management information accordingly.

The user can input the birth date of each pigling, the number of the piglings, the input environmental temperature control curve model, the temperature data model required by animal growth, the set environmental temperature value and other information at the WEB end and/or the mobile terminal 30 to generate user management information, or the user can directly input the information through the input device 410 of the management terminal 400 to generate corresponding user management information, and the user management information is stored in the server 20 and the management terminal 400 and is called by the intelligent control terminal 100. The input device 410 may be a touch screen, a physical key, or a touch key.

Optionally, the intelligent control terminal 100, the temperature sensor 200 and the intelligent heat preservation lamp 300 all include a plurality of ones; each intelligent heat preservation lamp 300 is connected with at least one temperature sensor 200 and one intelligent control terminal 100.

Each intelligent heat preservation lamp 300 is connected with at least one temperature sensor 200, as shown in fig. 3, the intelligent heat preservation lamp 300 is connected with one temperature sensor 200, in an alternative embodiment, the intelligent heat preservation lamp 300 is connected with a plurality of temperature sensors 200, so that the ambient temperature can be effectively monitored; each intelligent heat preservation lamp 300 performs data interaction with the management terminal 400, the server 20 and a user through the intelligent control terminal 100, so that the user can remotely know the state and multiple environmental temperatures of each intelligent heat preservation lamp 300 and adopt effective temperature regulation and control; the intelligent heat preservation lamp remote control system has the advantages that the user can remotely control each intelligent heat preservation lamp, and accordingly accurate control over the environment temperature is achieved.

As shown in fig. 2, optionally, the intelligent control terminal 100 further includes a monitoring chip 110, configured to obtain working state information of each intelligent heat preservation lamp 300 and upload the working state information to the management terminal 400; the intelligent control terminal 100 is further configured to obtain and store the user management information from the management terminal 400.

The monitoring chip monitors the working state of the intelligent heat preservation lamp 300 in real time, uploads the working state information to the management terminal 400 for storage, and generates a historical data file for storage according to the monitored working state, so that data tracing at the later stage is facilitated, and the management terminal 400 can upload the working state information of the intelligent heat preservation lamp 300 to the server 20 for backup storage; the intelligent control terminal 100 can also obtain and store user management information from the management terminal 400, which is convenient for the intelligent control terminal 100 to call. Further, when the control subsystem 10 is connected or not connected with the mobile terminal 30 and the server 20, the management terminal 400 can automatically acquire monitoring data of the intelligent control terminal and working state information of the intelligent heat preservation lamp 300, and intelligently control a plurality of connected intelligent control terminals according to programs and temperature setting data stored in the management terminal 400, so that the temperature of one or more pigsties can be intelligently regulated and controlled to meet the optimal growth requirement of the piglets.

Optionally, the intelligent control terminal 100 is further configured to generate an alarm instruction according to the monitoring data and the working state, and transmit the alarm instruction to the management terminal 400.

As shown in fig. 2, optionally, the management terminal 400 further includes a display module 420, configured to display alarm information corresponding to the monitoring data, the working state information, the user management information, and the alarm instruction; and is also used to transmit the alarm information to the server 20.

For example, the management terminal 400 may be a terminal device with a display module 420, which is arranged in a pigsty management room, and when the monitored ambient temperature of the pigsty is higher than or lower than a preset value and is still higher than or lower than the preset value after being intelligently adjusted by the intelligent control terminal 100, it may be determined that the intelligent heat preservation lamp 300 and/or the intelligent control terminal 100 has a fault, an alarm instruction is generated, and warning information is prompted at the management terminal 400; when the working state of the intelligent heat preservation lamp 300 is abnormal, an alarm instruction is generated, and warning information is reminded at the management terminal 400; further, the management terminal 400 transmits alarm information corresponding to the alarm instruction to the server 20, the server can transmit the alarm information to the mobile terminal 30 of the user through a wireless network for reminding, and the management terminal 400 forming the wireless networking can also directly transmit the alarm information to the mobile terminal 30 connected in the networking through the wireless network for reminding; reminding the user of adopting manual operation to realize temperature adjustment on the input device 410 through the warning information, when the manual adjustment still cannot be effective, continuously reminding the user to timely eliminate obstacles on the intelligent heat-preservation lamp 300 and/or the intelligent control terminal 100, and ensuring that the environmental temperature of the piglet is in a proper range. Furthermore, the display module 420 of the management terminal 400 can also display monitoring data, working state information and user management information, so that a user can know the conditions in the pigsty without entering the pigsty; meanwhile, maintenance is performed in time according to the working state display of each intelligent heat preservation lamp 300.

As shown in fig. 3, optionally, the intelligent control terminal 100 further includes at least one status indicator lamp 120 and an alarm (not shown), where the indicator lamp 120 is used to display the operating status information of the intelligent heat preservation lamp 300; the alarm is used for carrying out alarm prompt.

When a user enters a pigsty to remove obstacles and maintain the intelligent heat-preserving lamp 300, an object to be operated is rapidly found out according to the color of the status indicator lamp 120 and the alarm sound sent by the alarm, the efficiency of removing obstacles and maintaining of the user is improved, and the risk of infection of germs on piglets is reduced.

As shown in fig. 3, optionally, the intelligent heat preservation lamp 300 includes an intelligent heat preservation lamp main body 310, a waterproof connector 320, a connection wire 330, a switch 340 and a power plug 350;

the waterproof connector 320 is connected with the intelligent heat preservation lamp main body 310 and the connection wire 330, the power plug 350 is connected with an external power supply, and the switch 340 is used for manually turning on and off the intelligent heat preservation lamp 300.

For example, the temperature sensor 200 and the intelligent heat preservation lamp body 310 are both connected to the intelligent control terminal 100, and the diameter of the lamp shade at the head of the intelligent heat preservation lamp body 310 is 300mm, so that the heat radiation range of the intelligent heat preservation lamp 300 is large; the distance between the waterproof connector 320 and the tail of the intelligent heat preservation lamp body 310 is 500 mm; the distance between the waterproof connector 320 and the power plug 350 is 150mm, and the switch 340 is arranged on the connecting line 330 between the waterproof connector 320 and the power plug 350; the switch 340 and the power plug 350 are connected with the intelligent heat preservation lamp body 310 on the lower portion through the waterproof connector 320, the switch 340 and the power plug 350 are arranged to be higher than the ground, and short circuit caused by high humidity of the pigsty is avoided.

It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.

Claims (10)

1. An intelligent heat-preservation lamp control system is characterized by comprising a plurality of control subsystems and a server; the control subsystem includes: the intelligent heat preservation system comprises an intelligent control terminal, a temperature sensor, an intelligent heat preservation lamp and a management terminal; the intelligent control terminal and the management terminal both comprise Bluetooth modules;

the temperature sensor is connected with the intelligent control terminal and used for monitoring the ambient temperature in real time and transmitting monitoring data to the intelligent control terminal;

the intelligent control terminal is electrically connected with the intelligent heat-preservation lamp, is connected with the management terminal through the Bluetooth module, and is used for transmitting the received monitoring data to the management terminal for storage, and generating a first control instruction corresponding to the monitoring data according to calculation model calculation, and/or generating a corresponding first control instruction according to a second control instruction transmitted by the management terminal, and the intelligent control terminal adjusts the working power of the intelligent heat-preservation lamp according to the first control instruction;

the management terminals of the control subsystems are connected and wirelessly networked through the Bluetooth modules, are used for data interaction, and generate a second control instruction according to the operation of the mobile terminal connected with the management terminals; the management terminal is also connected with the server and used for uploading the received monitoring data to the server and receiving a second control instruction of the server;

and the server is used for backing up and storing the monitoring data and generating the second control instruction according to the operation of the WEB end and/or the mobile terminal connected with the WEB end.

2. The intelligent heat-preserving lamp control system according to claim 1, wherein the server is further configured to generate user management information according to input of a user at a WEB end and/or a mobile terminal, and transmit the user management information to the management terminal;

the management terminal also comprises an input device which is used for receiving the operation of the user and correspondingly generating the user management information.

3. The intelligent heat-preserving lamp control system according to claim 1, wherein the calculation model comprises an ambient temperature control curve model and a set ambient temperature value.

4. The intelligent heat-preserving lamp control system according to claim 1, wherein the intelligent control terminal, the temperature sensor and the intelligent heat-preserving lamp comprise a plurality of terminals; each intelligent heat preservation lamp is connected with at least one temperature sensor and one intelligent control terminal.

5. The intelligent heat-preserving lamp control system according to claim 2, wherein the intelligent control terminal further comprises a monitoring chip for acquiring the working state information of each intelligent heat-preserving lamp and uploading the information to the management terminal; and the intelligent control terminal is also used for acquiring and storing the user management information from the management terminal.

6. The intelligent heat-preserving lamp control system as claimed in claim 5, wherein the intelligent control terminal is further configured to generate an alarm instruction according to the monitoring data and the working state and transmit the alarm instruction to the management terminal.

7. The intelligent heat-preserving lamp control system as claimed in claim 6, wherein the management terminal further comprises a display module for displaying the monitoring data, the working state information, the user management information and the alarm information corresponding to the alarm instruction; and the alarm information is also transmitted to the server.

8. The intelligent heat-preserving lamp control system as claimed in claim 1, wherein the intelligent control terminal further comprises at least one status indicator lamp and an alarm;

the indicator light is used for displaying the working state information of the intelligent heat preservation light; the alarm is used for carrying out alarm prompt.

9. The intelligent heat-preserving lamp control system according to claim 1, wherein the intelligent control terminal comprises a silicon controlled voltage regulating circuit for adjusting the working voltage of the intelligent heat-preserving lamp according to the first control instruction so as to adjust the working power of the intelligent heat-preserving lamp.

10. The intelligent heat-preserving lamp control system according to claim 1, wherein the intelligent heat-preserving lamp comprises an intelligent heat-preserving lamp main body, a waterproof connector, a connecting wire, a switch and a power plug;

the waterproof connector is connected with the intelligent heat preservation lamp main body and the connecting wire, the power plug is connected with an external power supply, and the switch is used for manually opening and closing the intelligent heat preservation lamp.

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