CN114914987A - Lithium battery power supply device for energy-saving type fan heater and control method - Google Patents

Abstract

The invention discloses a lithium battery power supply device for an energy-saving fan, which comprises a shell, wherein a lithium battery is fixedly connected inside the shell, a control circuit positioned at the top of the lithium battery is arranged inside the shell, and the output end of the control circuit is in bidirectional electric connection with the input end of the lithium battery. According to the invention, the running data and the time are matched with each other through the battery power supply twin model establishing system to form the battery power supply twin model, the processor can adjust the running state of the lithium battery at each time interval through the control circuit according to the predicted data of the battery power supply twin model, the operation steps of manual timing adjustment of a user are saved, and the problems that the control mode of the lithium battery power supply device for the existing fan heater is single, the power supply device is generally required to be adjusted in a manual timing mode, time and labor are wasted, the intelligent control effect is not achieved, and the application range and the operation difficulty of the fan heater are seriously influenced are solved.

Description

Lithium battery power supply device for energy-saving type fan heater and control method

Technical Field

The invention relates to the technical field of power supply devices, in particular to a lithium battery power supply device for an energy-saving type fan heater and a control method.

Background

The lithium battery is needed to provide energy sources in the operation process of the fan heater, but the control mode of the lithium battery power supply device for the existing fan heater is single, the power supply device is generally needed to be adjusted in a manual timing mode, time and labor are wasted, the intelligent control effect is not achieved, and the application range and the operation difficulty of the fan heater are seriously influenced.

Disclosure of Invention

In order to solve the problems in the background art, the invention aims to provide an energy-saving lithium battery power supply device for a fan heater and a control method thereof, which have the advantage of intelligent control and solve the problems that the control mode of the existing lithium battery power supply device for the fan heater is single, the power supply device is generally required to be adjusted in a manual timing mode, time and labor are wasted, the effect of intelligent control is not achieved, and the application range and the operation difficulty of the fan heater are seriously influenced.

In order to achieve the purpose, the invention provides the following technical scheme: a lithium battery power supply device for an energy-saving fan heater comprises a shell;

the inside fixedly connected with lithium cell of the said body, the inside of the said body has control circuit located at top of lithium cell, the output of the said control circuit is connected with the two-way electricity of input end of the lithium cell, the left side of the said body has treatment boxes, the right side fixedly connected with circuit board of the said treatment box inner wall, the two-way electricity of surface of the said circuit board is connected with the processor, the output of the said processor is connected with the two-way electricity of input end of the control circuit, the said processor is that the internal operation has twin model of battery powered to set up the system, the two-way electricity of output end of the said twin model of battery powered to set up the system is connected with the autonomous learning system, the two-way electricity of surface of the said circuit board is connected with the data transceiver module, the two-way electricity of output end of the said processor is connected with the storage module, the two-way electricity of output end of the said data transceiver module is connected with the wireless gateway, the output end of the storage module is in bidirectional electric connection with the input end of the data receiving and transmitting module, and the output end of the wireless gateway is in bidirectional electric connection with the cloud server.

Preferably, the right side of the inner wall of the shell is fixedly connected with a monitoring system, the monitoring system consists of a voltage monitoring module and a current monitoring module, and the output end of the lithium battery is respectively in bidirectional electric connection with the input ends of the voltage monitoring module and the current monitoring module.

Preferably, the battery-powered twin model building system is composed of a logic model importing module, a conceptual model importing module and a timing module.

Preferably, the autonomous learning system is composed of a multidimensional convolution module and a self-coding module.

Preferably, the output end of the wireless gateway is electrically connected with a centralized sorting module in a bidirectional mode, long-term and short-term operation data are stored in the centralized sorting module, and the output end of the centralized sorting module is electrically connected with the input end of the cloud server.

Preferably, the output end of the cloud server is electrically connected with a feedback unit in a bidirectional manner, and the output end of the feedback unit is electrically connected with a mobile terminal in a bidirectional manner.

Preferably, the output end of the lithium battery is inserted with a cable connector, the surface of the cable connector is sleeved with an extrusion plate, the surface of the cable connector is fixedly connected with an extension plate positioned inside the extrusion plate, the front surface and the back surface of the extrusion plate are fixedly connected with sleeve plates positioned on two sides of the shell, the left side of each sleeve plate is fixedly connected with a transmission plate, and a structure for driving the transmission plates to move is arranged inside the treatment box.

Preferably, the structure for driving the transmission plate to move comprises an electric telescopic rod fixedly connected inside the treatment box, and an output end of the electric telescopic rod penetrates through the left side of the treatment box and is fixedly connected with the right side of the transmission plate.

Preferably, the surface of the sleeve plate is provided with a limiting groove, the front surface and the back surface of the shell are fixedly connected with limiting rods positioned in the limiting groove, and the limiting rods are in sliding connection with the limiting groove.

A control method of a lithium battery power supply device for an energy-saving fan heater comprises the following steps:

s1: the monitoring system can be used for monitoring the operation data of the lithium battery in real time and transmitting the operation data to the circuit board, and the processor stores the operation data to the storage module;

s2: the processor runs the battery power supply twin model building system, the processor extracts long-term and short-term running data stored in the cloud server through the wireless gateway and the data transceiving module and conducts the long-term and short-term running data to the interior of the battery power supply twin model building system, the battery power supply twin model building system matches the running data with time to form a battery power supply twin model, and the processor can regulate running states of the lithium battery in all periods through the control circuit according to predicted data of the battery power supply twin model;

s3: when the fan heater needs to be shut down, the electric telescopic handle can control the driving plate to move towards the right side, the driving plate pushes the extrusion plate to move synchronously through the sleeve plate, the extrusion plate utilizes the extension plate to drive the cable joint to move synchronously, and when the cable joint is separated from the output end of the lithium battery, the effect of breaking the circuit of the lithium battery is achieved, and the energy transmission loss is reduced.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the control data of the lithium battery is recorded by the processor and stored in the storage module, the processor runs the battery power supply twin model building system, the battery power supply twin model building system matches the running data with time to form a battery power supply twin model, the processor can adjust the running state of the lithium battery at each time period through the control circuit according to the prediction data of the battery power supply twin model, so that the operation steps of manual timing adjustment of a user are saved, and the problems that the control mode of the lithium battery power supply device for the existing fan heater is single, the power supply device is generally adjusted in a manual timing mode, time and labor are wasted, the intelligent control effect is not achieved, and the application range and the operation difficulty of the fan heater are seriously influenced are solved.

2. According to the invention, by arranging the monitoring system, the voltage monitoring module and the current monitoring module, the operation state of the lithium battery can be monitored in real time, and the processor can conveniently acquire and record the operation data of the lithium battery.

3. According to the invention, the logic model import module, the concept model import module and the timing module are arranged, so that the model building accuracy can be improved, and the processor can accurately adjust the running state of the lithium battery.

4. According to the invention, the intelligent degree of the battery power supply twin model building system can be improved and the data operation efficiency can be improved by arranging the multidimensional convolution module and the self-coding module.

5. By arranging the centralized arrangement module and the long-term and short-term operation data, the invention can perform centralized storage on a large amount of operation data of the lithium batteries, and is convenient for the autonomous learning system to learn the data.

6. According to the invention, the feedback unit and the mobile terminal are arranged, so that the user can be prompted, and the safety degree of the control system is improved.

7. According to the invention, the cable joint, the extrusion plate, the extension plate and the sleeve plate are arranged, so that the cable joint can be extruded and fixed, and the cable joint and the lithium battery can be conveniently separated in an open circuit mode.

8. According to the invention, the electric telescopic rod is arranged, so that the automation degree of the extrusion plate can be improved, and the operation steps of manually moving the extrusion plate in a reciprocating manner by a user are saved.

9. According to the invention, the sleeve plate can be fixed by arranging the limiting groove and the limiting rod, so that the phenomenon that the sleeve plate is inclined in the moving process is avoided.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic sectional view of the housing structure of the present invention;

FIG. 3 is a schematic sectional view of the structure of the treatment tank of the present invention;

FIG. 4 is a perspective view of a portion of the present invention;

FIG. 5 is a schematic diagram of the system of the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 1 according to the present invention.

In the figure: 1. a housing; 2. a lithium battery; 3. a control circuit; 4. a treatment tank; 5. a circuit board; 6. a processor; 7. a battery power supply twin model establishing system; 8. an autonomous learning system; 9. a data transceiver module; 10. a storage module; 11. a wireless gateway; 12. a cloud server; 13. a monitoring system; 14. a voltage monitoring module; 15. a current monitoring module; 16. a logic model import module; 17. a conceptual model import module; 18. a timing module; 19. a multidimensional convolution module; 20. a self-encoding module; 21. a centralized arrangement module; 22. long and short term operational data; 23. a feedback unit; 24. a mobile terminal; 25. a cable joint; 26. a pressing plate; 27. an extension plate; 28. sheathing; 29. a drive plate; 30. an electric telescopic rod; 31. a limiting groove; 32. a limiting rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 6, the lithium battery power supply device for an energy-saving fan heater provided by the invention comprises a housing 1;

the inside of a shell 1 is fixedly connected with a lithium battery 2, the inside of the shell 1 is provided with a control circuit 3 positioned at the top of the lithium battery 2, the output end of the control circuit 3 is bidirectionally and electrically connected with the input end of the lithium battery 2, the left side of the shell 1 is provided with a processing box 4, the right side of the inner wall of the processing box 4 is fixedly connected with a circuit board 5, the surface of the circuit board 5 is bidirectionally and electrically connected with a processor 6, the output end of the processor 6 is bidirectionally and electrically connected with the input end of the control circuit 3, the processor 6 is internally provided with a battery power supply twin model establishing system 7, the output end of the battery power supply twin model establishing system 7 is bidirectionally and electrically connected with an autonomous learning system 8, the surface of the circuit board 5 is bidirectionally and electrically connected with a data receiving and sending module 9, the output end of the processor 6 is bidirectionally and electrically connected with a storage module 10, and the output end of the data receiving and sending module 9 is bidirectionally and electrically connected with a wireless gateway 11, the output end of the storage module 10 is bidirectionally and electrically connected with the input end of the data transceiver module 9, and the output end of the wireless gateway 11 is bidirectionally and electrically connected with the cloud server 12.

Referring to fig. 6, a monitoring system 13 is fixedly connected to the right side of the inner wall of the casing 1, the monitoring system 13 is composed of a voltage monitoring module 14 and a current monitoring module 15, the output end of the lithium battery 2 is respectively in bidirectional electrical connection with the input ends of the voltage monitoring module 14 and the current monitoring module 15, and the voltage monitoring module 14 and the current monitoring module 15 are current voltmeters in the prior art.

As a technical optimization scheme of the invention, the monitoring system 13, the voltage monitoring module 14 and the current monitoring module 15 are arranged, so that the running state of the lithium battery 2 can be monitored in real time, and the processor 6 can conveniently acquire and record the running data of the lithium battery 2.

Referring to fig. 5, the battery-powered twin model building system 7 is composed of a logical model importing module 16, a conceptual model importing module 17, and a timing module 18, and the timing module 18 is a timer in the related art.

As a technical optimization scheme of the invention, the logic model import module 16, the conceptual model import module 17 and the timing module 18 are arranged, so that the model building accuracy can be improved, and the processor 6 can accurately adjust the running state of the lithium battery 2.

Referring to fig. 5, the autonomous learning system 8 is composed of a multidimensional convolution module 19 and a self-encoding module 20, and the multidimensional convolution module 19 can reduce data from multiple dimensions to one dimension.

As a technical optimization scheme of the invention, the intelligent degree of the battery power supply twin model building system 7 can be improved and the data operation efficiency can be improved by arranging the multidimensional convolution module 19 and the self-coding module 20.

Referring to fig. 2, the output end of the wireless gateway 11 is electrically connected to a centralized management module 21 in a bidirectional manner, long-term and short-term operation data 22 is stored in the centralized management module 21, and the output end of the centralized management module 21 is electrically connected to the input end of the cloud server 12.

As a technical optimization scheme of the invention, by arranging the centralized sorting module 21 and the long-term and short-term operation data 22, a large amount of operation data of the lithium battery 2 can be stored in a centralized manner, so that the autonomous learning system 8 can learn the data conveniently.

Referring to fig. 3, the output end of the cloud server 12 is electrically connected to a feedback unit 23 in both directions, the output end of the feedback unit 23 is electrically connected to a mobile terminal 24 in both directions, and the mobile terminal 24 is a mobile phone in the prior art.

As a technical optimization scheme of the invention, the feedback unit 23 and the mobile terminal 24 are arranged, so that a user can be prompted, and the safety degree of the control system is improved.

Referring to fig. 1, the output of lithium cell 2 is pegged graft and is had cable joint 25, and cable joint 25's surperficial cover is equipped with stripper plate 26, and cable joint's fixed surface is connected with the extension board 27 that is located stripper plate 26 inside, and the front of stripper plate 26 and the equal fixedly connected with in back are located the lagging 28 of casing 1 both sides, and the left side fixedly connected with driving plate 29 of lagging 28, the inside of handling case 4 is provided with the structure that is used for driving plate 29 and removes.

As a technical optimization scheme of the invention, the cable connector 25 can be extruded and fixed by arranging the cable connector 25, the extrusion plate 26, the extension plate 27 and the sleeve plate 28, so that the cable connector 25 and the lithium battery 2 can be conveniently disconnected and separated.

Referring to fig. 1, the structure for driving the driving plate 29 to move includes an electric telescopic rod 30 fixedly connected inside the treatment box 4, and an output end of the electric telescopic rod 30 penetrates through to the left side of the treatment box 4 and is fixedly connected with the right side of the driving plate 29.

As a technical optimization scheme of the present invention, by providing the electric telescopic rod 30, the degree of automation of the squeezing plate 26 can be improved, and the operation steps of manually moving the squeezing plate 26 back and forth by a user are saved.

Referring to fig. 1, a limiting groove 31 is formed on the surface of the sleeve plate 28, a limiting rod 32 located inside the limiting groove 31 is fixedly connected to both the front surface and the back surface of the housing 1, and the limiting rod 32 is slidably connected to the limiting groove 31.

As a technical optimization scheme of the invention, the sleeve plate 28 can be fixed by arranging the limiting groove 31 and the limiting rod 32, so that the phenomenon that the sleeve plate 28 inclines in the moving process is avoided.

Referring to fig. 1, a method for controlling a lithium battery power supply device for an energy-saving fan heater includes the following steps:

s1: the monitoring system can monitor the operation data of the lithium battery 2 in real time and transmit the operation data to the circuit board 5, and the processor 6 stores the data in the storage module 10;

s2: the processor 6 operates the battery power supply twin model establishing system 7, the processor 6 extracts the long-term and short-term operation data 22 stored in the cloud server 12 through the wireless gateway 11 and the data transceiving module 9 and transmits the data to the interior of the battery power supply twin model establishing system 7, the battery power supply twin model establishing system 7 matches the operation data with time to form a battery power supply twin model, and the processor 6 can adjust the operation state of the lithium battery 2 in each period through the control circuit 3 according to the prediction data of the battery power supply twin model;

s3: when the fan heater needs to be stopped, the electric telescopic rod 30 can control the transmission plate 29 to move towards the right side, the transmission plate 29 pushes the extrusion plate 26 to move synchronously through the sleeve plate 28, the extrusion plate 26 drives the cable connector 25 to move synchronously through the extension plate 27, and when the cable connector 25 is separated from the output end of the lithium battery 2, the effect of breaking the lithium battery 2 is achieved, and energy transmission loss is reduced.

The working principle and the using process of the invention are as follows: when the device is used, a user regulates the lithium battery 2 in advance through the control circuit 3 and provides energy for the fan heater through the lithium battery 2, the monitoring system can monitor the operation data of the lithium battery 2 in real time and transmit the data to the circuit board 5 in the operation process of the lithium battery 2, the processor 6 stores the data into the storage module 10, the processor 6 operates the battery power supply twin model establishing system 7, the processor 6 extracts the long-term and short-term operation data 22 stored in the cloud server 12 through the wireless gateway 11 and the data receiving and transmitting module 9 and transmits the data into the battery power supply twin model establishing system 7, the battery power supply model establishing system 7 matches the operation data with time to form a battery power supply twin model, the processor 6 can regulate the operation state of the lithium battery 2 in each time period through the control circuit 3 according to the prediction data of the battery power supply twin model, the operating procedure who saves the artifical timing of user and adjust, when the electric fan heater needs to be shut down, electric telescopic handle 30 can control driving plate 29 and remove to the right side, driving plate 29 promotes stripper plate 26 synchronous motion through lagging 28, stripper plate 26 utilizes extension board 27 to drive cable joint 25 synchronous motion, when cable joint 25 and lithium cell 2's output break away from the contact, reach the effect of opening circuit to lithium cell 2, reduce energy transmission loss.

In summary, the following steps: the lithium battery power supply device for the energy-saving fan heater and the control method thereof record the control data of the lithium battery 2 through the processor 6 and store the data into the storage module 10, meanwhile, the processor 6 operates the battery power supply twin model establishing system 7, the battery power supply twin model establishing system 7 matches operation data with time to enable the operation data and the time to form a battery power supply twin model, the processor 6 can adjust the operation state of the lithium battery 2 in each period through the control circuit 3 according to prediction data of the battery power supply twin model, operation steps of manual timing adjustment of a user are saved, and the problems that the control mode of the lithium battery power supply device for the existing fan heater is single, the power supply device is generally required to be adjusted in a manual timing mode, time and labor are wasted, the intelligent control effect is not achieved, and the application range and operation difficulty of the fan heater are seriously affected are solved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A lithium battery power supply device for an energy-saving fan heater comprises a shell (1);

the method is characterized in that: the inside fixedly connected with lithium cell (2) of casing (1), the inside of casing (1) is provided with control circuit (3) that is located lithium cell (2) top, the output of control circuit (3) is connected with the two-way electricity of the input of lithium cell (2), the left side of casing (1) is provided with handles case (4), the right side fixedly connected with circuit board (5) of handling case (4) inner wall, the two-way electricity in surface of circuit board (5) is connected with treater (6), the output of treater (6) is connected with the two-way electricity of the input of control circuit (3), it is inside operation that treater (6) have battery power supply to give birth to twin model and establish system (7), the two-way electricity in output of battery power supply twin model and establish system (7) is connected with autonomic learning system (8), the two-way electricity in surface of circuit board (5) is connected with data transceiver module (9), the bidirectional electric connection of the output of treater (6) has storage module (10), the bidirectional electric connection of the output of data transceiver module (9) has wireless gateway (11), the output of storage module (10) is connected with the bidirectional electric connection of the input of data transceiver module (9), the bidirectional electric connection of the output of wireless gateway (11) has high in the clouds server (12).

2. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the right side fixedly connected with monitored control system (13) of casing (1) inner wall, monitored control system (13) comprise voltage monitoring module (14) and current monitoring module (15), the output of lithium cell (2) is connected with the input two-way electricity of voltage monitoring module (14) and current monitoring module (15) respectively.

3. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the battery power supply twin model establishing system (7) is composed of a logic model leading-in module (16), a conceptual model leading-in module (17) and a timing module (18).

4. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the autonomous learning system (8) is composed of a multi-dimensional convolution module (19) and a self-coding module (20).

5. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the output both-way electricity of wireless gateway (11) is connected with concentrates arrangement module (21), long short-term operation data (22) are stored to the inside of concentrating arrangement module (21), the output of concentrating arrangement module (21) and the input electric connection of high in the clouds server (12).

6. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the output end of the cloud server (12) is electrically connected with a feedback unit (23) in a two-way mode, and the output end of the feedback unit (23) is electrically connected with a mobile terminal (24) in a two-way mode.

7. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the utility model discloses a lithium battery pack, including lithium cell (2), the output of lithium cell (2) is pegged graft and is had cable joint (25), the surface cover of cable joint (25) is equipped with stripper plate (26), cable joint's fixed surface is connected with extension board (27) that are located stripper plate (26) inside, the front of stripper plate (26) and the equal fixedly connected with in the back nest plate (28) that the back is located casing (1) both sides, the left side fixedly connected with driving plate (29) of nest plate (28), the inside of handling case (4) is provided with the structure that is used for driving plate (29) and removes.

8. The lithium battery power supply device for the energy-saving fan heater according to claim 7, wherein: the structure for driving the transmission plate (29) to move comprises an electric telescopic rod (30) fixedly connected inside the treatment box (4), and the output end of the electric telescopic rod (30) penetrates through the left side of the treatment box (4) and is fixedly connected with the right side of the transmission plate (29).

9. The lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: spacing groove (31) have been seted up on the surface of lagging (28), the equal fixedly connected with in front and the back of casing (1) is located inside gag lever post (32) of spacing groove (31), gag lever post (32) and spacing groove (31) sliding connection.

10. The control method of the lithium battery power supply device for the energy-saving fan heater according to claim 1, characterized in that: the method comprises the following steps:

s1: the monitoring system can be used for monitoring the operation data of the lithium battery (2) in real time and transmitting the operation data to the circuit board (5), and the processor (6) stores the data to the storage module (10);

s2: the processor (6) operates the battery power supply twin model establishing system (7), the processor (6) extracts long-term and short-term operation data (22) stored in the cloud server (12) through the wireless gateway (11) and the data transceiving module (9) and conducts the long-term and short-term operation data to the interior of the battery power supply twin model establishing system (7), the battery power supply twin model establishing system (7) matches the operation data with time to enable the operation data to form a battery power supply twin model, and the processor (6) can adjust the operation state of the lithium battery (2) in each period through the control circuit (3) according to the prediction data of the battery power supply twin model;

s3: when the fan heater needs to be shut down, electric telescopic handle (30) can control driving plate (29) and move to the right side, driving plate (29) pass through lagging (28) and promote stripper plate (26) synchronous motion, stripper plate (26) utilize extension board (27) to drive cable joint (25) synchronous motion, when cable joint (25) and the output of lithium cell (2) break away from the contact, reach the effect of opening circuit to lithium cell (2), reduce energy transmission loss.

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