CN111023210B - High-voltage power supply system of intelligent oil fume purifier and control method - Google Patents

Abstract

The application discloses intelligence oil smoke clarifier high voltage power supply system and control method, wherein, intelligence oil smoke clarifier high voltage power supply system control method includes: acquiring collected data; analyzing the collected data and generating an analysis result; selecting a high-voltage power supply to be started and a corresponding working mode according to an analysis result; and issuing a working instruction to the high-voltage power supply to be started, and receiving the fed back operation information. The application has the technical effects of saving energy, still being capable of continuously working after the high-voltage power supply fails and facilitating maintenance.

Description

High-voltage power supply system of intelligent oil fume purifier and control method

Technical Field

The application relates to the technical field of power supplies for intelligent oil fume purifiers, in particular to a high-voltage power supply system for an intelligent oil fume purifier and a control method.

Background

The oil smoke clarifier is widely used in the oil smoke purification treatment of kitchens such as families, hotels, restaurants or dining halls, the existing oil smoke purification system adopts a single high-voltage power supply, when the oil smoke purification system works, the energy consumption is large, and the high-voltage power supply can not continue to work normally after being out of order.

In addition, the repair of the faulty component is time consuming and laborious.

Disclosure of Invention

The application aims to provide the high-voltage power supply of the intelligent oil fume purifier and the control method, and the technical effects of saving energy, continuing working after the high-voltage power supply fails and facilitating maintenance are achieved.

In order to achieve the above object, the present application provides a method for controlling a high voltage power supply system of an intelligent oil fume purifier, comprising: acquiring collected data; analyzing the collected data and generating an analysis result; selecting a high-voltage power supply to be started and a corresponding working mode according to an analysis result; and issuing a working instruction to the high-voltage power supply to be started, and receiving the fed back operation information.

As above, wherein the sub-steps of analyzing the collected data and generating the analysis result are as follows: judging whether the acquired data are completely acquired or not according to the data items; if the acquisition is incomplete, sending an acquisition device overhaul alarm and enumerating data items of missing acquired data; and if the acquisition is complete, determining the working component needing to be started and the power required to be operated according to the acquired data, and generating an analysis result.

The sub-steps of determining the working components to be started and the power required to operate the working components according to the collected data are as follows: acquiring data content of a data item; determining a working component needing to be started according to the data content, and calling a power meter of the working component; and calculating to obtain the selected parameters, and determining the required operating power according to the power meter by using the selected parameters.

As above, the expression for calculating the selected parameter is as follows: XY-BZ × YZ-SJ-GS; wherein, SJ ═ CG/(HG × y 1); HG ═ U1/y 2; u1 ═ U2/U; wherein XY represents a selected parameter; BZ represents the standard oil smoke concentration allowed to be discharged, YZ represents a factor, and the factor is set according to the setting environment and the operation mode of the working component; SJ represents the actual oil smoke concentration collected by the collector; GS represents a preset fixed value; CG is the received feedback light intensity value of the collector; HG is the detection light intensity value sent by the collector; y1 is a first consumption parameter, which is a molecular consumption parameter of the detected light; u1 is the input voltage of the feedback light received by the collector; y2 is a second consumption parameter value, which is a molecular consumption parameter of the feedback light; u2 is the output voltage of the collector sending detection light; u is the voltage gain.

As above, if the feedback operation information is not received or the received operation information is incorrect, it is determined that the high voltage power supply fails, and an alarm instruction is issued, and the failed high voltage power supply is cut off and the standby high voltage power supply is started.

The application provides an intelligence oil smoke clarifier high voltage power supply system includes: the device comprises a controller, at least one collector, a plurality of high-voltage power supplies and a plurality of working components; the high-voltage power supplies are connected with the working components in a one-to-one correspondence manner; each high-voltage power supply is in signal connection with the controller; each collector is in signal connection with the controller; wherein, the controller: the intelligent oil fume purifier high-voltage power supply system control method is used for executing any one of the above methods; a collector: the controller is used for acquiring the acquired data and uploading the acquired data to the controller; a high-voltage power supply: selecting a working mode according to a working instruction issued by the controller, and providing a working power supply for a corresponding working component; a working part: and the operation is carried out according to the power supply provided by the high-voltage power supply.

As above, wherein the controller comprises: the device comprises a receiving unit, a processing unit, a storage unit and a power supply unit; wherein the receiving unit: the data acquisition unit is used for receiving the acquired data uploaded by the acquisition unit, analyzing the acquired data, generating an analysis result and uploading the analysis result to the processing unit; a processing unit: the device is used for receiving the analysis result sent by the receiving unit and selecting a high-voltage power supply to be started and a corresponding working mode according to the analysis result; generating a working instruction for a high-voltage power supply to be started and a corresponding working mode; issuing a working instruction to a high-voltage power supply to be started, and receiving feedback operation information; a storage unit: the system is used for storing the received collected data and the operation information; a power supply unit: for powering the receiving unit, the processing unit and the storage unit.

As above, wherein the operational component comprises a fault alarm.

As above, wherein, a standby high-voltage power supply is also included; the standby high-voltage power supply is in signal connection with the controller and is respectively connected with each working component.

The above, wherein each high voltage power supply has at least one operating mode.

The application has the technical effects of saving energy, still being capable of continuously working after the high-voltage power supply fails and facilitating maintenance.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present application, and other drawings can be obtained by those skilled in the art according to the drawings.

FIG. 1 is a schematic structural diagram of an embodiment of a high voltage power supply system of an intelligent lampblack purifier;

fig. 2 is a flowchart of an embodiment of a control method of the intelligent lampblack purifier high-voltage power supply system.

Detailed Description

The technical solutions in the embodiments of the present invention are 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 some, not all, embodiments of the present invention. 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.

The application provides an intelligent oil smoke clarifier high voltage power supply system and control method, has the energy can be saved, high voltage power supply still can continue work and convenient technical effect who overhauls after breaking down.

As shown in fig. 1, the present application provides an intelligent oil fume purifier high voltage power supply system, comprising: the device comprises a controller 1, at least one collector 2, a plurality of high-voltage power supplies 3 and a plurality of working components 4; the high-voltage power supplies 3 are connected with the working components 4 in a one-to-one correspondence manner; each high-voltage power supply 3 is in signal connection with the controller 1; each collector 2 is in signal connection with the controller 1.

Wherein, the controller 1: the method is used for executing the control method of the intelligent oil fume purifier high-voltage power supply system.

And a collector 2: the controller is used for collecting the collected data and uploading the collected data to the controller.

Specifically, the collector 2 is a plurality of, and a plurality of collectors 2 include oil smoke concentration collector, temperature collector, image collector and pronunciation collector at least.

Specifically, as an embodiment, the oil smoke concentration collector is a high-sensitivity oil smoke concentration testing device.

The high-voltage power supply 3: and selecting the working mode according to the working instruction sent by the controller 1, and providing working power supply for the corresponding working component 4.

Specifically, the intelligent high-voltage power supply system of the oil fume purifier also comprises a standby high-voltage power supply; the standby high-voltage power supply is respectively connected with each working component

The working member 4: operating from the power supplied by the high voltage power supply 3.

Further, the working components 4 are plural, and the plural working components at least include: the working part is used for purifying oil smoke, the working part is used for exhausting air and the working part is used for cleaning.

Further, the working part 4 also comprises a malfunction alarm. The failure alarm is used for receiving an alarm command from the controller 1 and giving an alarm.

Further, the working unit 4 further comprises a display for displaying the missing items of collected data.

Furthermore, the intelligent high-voltage power supply system of the oil fume purifier also comprises a standby high-voltage power supply; the standby high-voltage power supply is in signal connection with the controller 1 and is respectively connected with each working component 4.

Further, each high voltage power supply 3 has at least one operation mode.

Further, the controller 1 includes: the device comprises a receiving unit, a processing unit, a storage unit and a power supply unit; a receiving unit: the data acquisition unit is used for receiving the acquired data uploaded by the acquisition unit, analyzing the acquired data, generating an analysis result and uploading the analysis result to the processing unit.

Wherein the processing unit: the device is used for receiving the analysis result sent by the receiving unit and selecting a high-voltage power supply to be started and a corresponding working mode according to the analysis result; generating a working instruction for a high-voltage power supply to be started and a corresponding working mode; and issuing a working instruction to the high-voltage power supply to be started, and receiving the fed back operation information.

A storage unit: for storing the received acquisition data and operational information.

A power supply unit: for powering the receiving unit, the processing unit and the storage unit.

As shown in fig. 2, the present application provides a method for controlling a high-voltage power supply system of an intelligent oil fume purifier, comprising:

s1: and acquiring the acquired data.

Specifically, the substeps of acquiring the collected data by the controller 1 are as follows:

s110: and receiving a starting instruction.

Specifically, as an embodiment, after the user turns on the high-voltage power supply system of the intelligent oil fume purifier, the collector 2 is powered on, the controller 1 automatically sends a start instruction to the collector 2, and the collector 2 executes S120 after receiving the start instruction.

As another embodiment, after the user turns on the high-voltage power supply system of the intelligent oil fume purifier, the collector 2 is powered on, after receiving the electric signal, the collector 2 takes the electric signal as a start instruction, and after receiving the start instruction, the collector 2 executes S120.

S120: and responding to the starting instruction to collect data.

Specifically, the collector 2 starts the working state in response to the start instruction, and collects data in real time before receiving the end instruction, and the data collected in real time is collected data.

Specifically, the collected data includes a plurality of data items, and the plurality of data items at least include: oil smoke data, temperature data, use area image data, and voice data. The use area image data is a video or a picture of the use area of the intelligent oil fume purifier high-voltage power supply system, such as: when cooking and frying in the kitchen cooking bench area, the controller processes the collected video of the working state of the boiler cooking bench, if the flame exceeds a set position, the fire hazard is judged to exist, and an alarm instruction is sent to the fault alarm. The voice data is voice of a user and can be voice instructions, such as turning on a fan or turning off the fan.

S130: and uploading the collected data.

Specifically, the collector 2 uploads the collected data to the controller 1.

S2: and analyzing the collected data and generating an analysis result.

Specifically, the controller 1 receives the collected data uploaded by the collector 2 through the receiving unit, analyzes the collected data, generates an analysis result, and sends the analysis result to the processing unit.

Specifically, the substeps of analyzing the collected data and generating the analysis result are as follows:

s210: and judging whether the acquired data is completely acquired or not according to the data items.

Specifically, as an embodiment, the data items for collecting the complete collected data include oil smoke data, temperature data, use area image data, and voice data.

If the received data items of the collected data include oil smoke data, temperature data, image data of the use area and voice data, the collection is complete, and S220 is executed.

If the data item of the received collected data lacks any one or more of oil smoke data, temperature data, image data of a use area and voice data, the collection is incomplete, and the controller 1 sends out a collector maintenance alarm to a user and lists the missing data item of the collected data.

Specifically, for example: if the collected data lack temperature data and voice data, the controller 1 sends an alarm collector maintenance alarm to the user through the fault alarm, and displays the data items of the missing collected data to the user through the display, so that the user can conveniently determine the position where the collector needs to be maintained.

S220: and determining the working components needing to be started and the power required to be operated according to the collected data, and generating an analysis result.

Specifically, the controller 1 analyzes the data content of each data item in the collected data through the receiving unit, determines the working component to be started and the power required to operate the working component according to the data content, and generates an analysis result, wherein the analysis result includes the working component to be started and the power required to operate the working component.

Further, as an embodiment, the sub-step of determining the working components to be started and the power required to be operated according to the collected data is as follows:

p1: data content of the data item is acquired.

P2: and determining the working component needing to be started according to the data content, and calling a power meter of the working component.

Specifically, a storage unit of the controller 1 preselects and stores power tables of each working component, each power table includes a plurality of power intervals, each power interval corresponds to a table head number, the table head numbers sequentially correspond to 0-M from high to low of the load of the working component, and M is greater than 1. Taking M ═ 9 as an example for explanation, at this time, the power interval has 10 header numbers, and assuming that the load of the working component is 0-W (MW), then W-0(MW) can be divided equally into 10 power intervals, each power interval corresponds to one header number, and the 10 power intervals correspond to the header numbers 0-M in sequence from high to low of the load of the working component, that is, when the boiler load is W (MW), the corresponding header number 0 is corresponded to, and at this time, the output power of the high-voltage power supply corresponding to the working component is the maximum, that is, the rated power; when the boiler load is 0, corresponding to the header number 9, the high voltage power supply corresponding to the working part is operated in the low power consumption mode at this time. Also for example, when the load required of the working part is 50% x w (mw), it corresponds to the header number 5.

P3: and calculating to obtain the selected parameters, and determining the required operating power according to the power meter by using the selected parameters.

Specifically, the expression for calculating the selected parameter is as follows:

XY＝BZ×YZ-SJ-GS；

wherein, SJ ═ CG/(HG × y 1);

HG＝U1/y2；

U1＝U2/u；

wherein XY represents the selection parameter; BZ represents the standard oil smoke concentration allowed to be discharged, YZ represents a factor, and the factor is set according to the setting environment and the operation mode of the working component; SJ represents the actual oil smoke concentration collected by the collector; GS represents a preset fixed value; CG is the received feedback light intensity value of the collector; HG is the detection light intensity value sent by the collector; y1 is a first consumption parameter, which is a molecular consumption parameter of the detected light; u1 is the input voltage of the feedback light received by the collector; y2 is a second consumption parameter value, which is a molecular consumption parameter of the feedback light; u2 is the output voltage of the collector sending detection light; u is the voltage gain.

The gauge head number corresponding to the load actually required by the working part is adjusted by selecting parameters so as to adjust the working mode of the high-frequency power supply corresponding to the working part according to the actually acquired oil smoke concentration, so that the oil smoke removal efficiency of the working part can meet emission regulations.

Specifically, the soot data includes at least one index item, and the at least one index item includes one or more items of soot particles, water vapor, carbon monoxide, carbon dioxide, or nitrogen oxides. As an example, the oil smoke data in the data item is described as an example.

T1: analyzing each index item in the oil smoke data to determine the oil smoke components.

Specifically, the processing unit analyzes each index item in the oil smoke data, and if the value of the index item is zero, the collected oil smoke components do not contain the index item; if the value of the index item is greater than zero, then collectedThe oil smoke component contains the index item. For example: the concentration of the oil smoke particles in the analyzed oil smoke data is 30mg/m²The concentration of water vapor is 10mg/m²And carbon monoxide at 0mg/m²Then, it is determined that the smoke components include smoke particles and moisture, and do not include carbon monoxide.

T2: and determining the working parts to be started according to the oil smoke components.

Specifically, as one example, the smoke component includes smoke particles and moisture, and does not include carbon monoxide. Because this oil smoke composition includes oil smoke particle and steam, then processing unit judges for the working part that needs to start to be used for purifying the oil smoke and the working part that is used for convulsions, and the working part that needs to start promptly includes: a working part for purifying oil smoke and a working part for air draft.

As another example, the concentration of soot particles is 0mg/m²The discharged smoke is fresh air, and working parts for purifying the oil smoke do not need to be started; only the working components for air extraction need to be activated.

T3: and analyzing the concentration range of the oil fume components, and determining the required operation power of the working part required to be started.

Specifically, as an example, the concentration of soot particles is 0mg/m²The exhausted smoke is fresh air, and the power required for running the working components for air draft is only 600W.

T4: and generating an analysis result of the working component required to be started and the power required to be operated.

Specifically, the receiving unit generates an analysis result according to the determined working element required to be started and the power required to be operated, and executes S3.

S3: and selecting a high-voltage power supply to be started and a corresponding working mode according to the analysis result.

Specifically, the processing unit receives the analysis result sent by the receiving unit, and determines a high-voltage power supply to be started according to the working component to be started in the analysis result, namely the high-voltage power supply to be started is a high-voltage power supply for supplying power to the working component to be started; and determining the working mode of the high-voltage power supply to be started according to the required running power in the analysis result.

The operation modes of the high voltage power supply 3 include a sleep mode, a low power mode, a normal power mode, and a high power mode.

S4: and issuing a working instruction to the high-voltage power supply to be started, and receiving the fed back operation information.

Specifically, the substeps of issuing a work instruction to the high-voltage power supply to be started and receiving the feedback operation information are as follows:

s410: and generating a work order.

Specifically, the processing unit generates a work instruction for the confirmed required work mode, and executes S420.

S420: and issuing the working instruction to the corresponding high-voltage power supply to be started, and receiving the operation information.

Specifically, the processing unit issues the generated working instruction to the corresponding to-be-started high-voltage power supply, and after receiving the working instruction, the to-be-started high-voltage power supply performs work in response to the working instruction and feeds back the operation information of the high-voltage power supply to the processing unit.

The working parts which do not receive the working instruction are all in the dormant mode, and the arrangement is favorable for saving energy and reducing power consumption.

Further, if the processing unit does not receive the fed back operation information or the received operation information is wrong, the high-voltage power supply is judged to be in fault, an alarm instruction is issued to the fault alarm, and the fault high-voltage power supply is cut off and the standby high-voltage power supply is started.

The application has the technical effects of saving energy, still being capable of continuously working after the high-voltage power supply fails and facilitating maintenance.

While the preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, the scope of protection of the present application is intended to be interpreted to include the preferred embodiments and all variations and modifications that fall within the scope of the present application. It will be apparent to those skilled in the art that various changes and modifications may be made in the present application without departing from the spirit and scope of the application. Thus, if such modifications and variations of the present application fall within the scope of the present application and their equivalents, the present application is intended to include such modifications and variations as well.

Claims (8)

1. A control method for a high-voltage power supply system of an intelligent oil fume purifier is characterized by comprising the following steps:

acquiring collected data;

analyzing the collected data and generating an analysis result;

selecting a high-voltage power supply to be started and a corresponding working mode according to an analysis result;

issuing a working instruction to a high-voltage power supply to be started, and receiving feedback operation information;

if the feedback operation information is not received or the received operation information is wrong, the high-voltage power supply is judged to be in fault, an alarm instruction is issued, and meanwhile, the fault high-voltage power supply is cut off and a standby high-voltage power supply is started;

the substeps of analyzing the collected data and generating an analysis result are as follows:

judging whether the acquired data are completely acquired or not according to the data items; wherein the data items include at least: oil smoke data, temperature data, use area image data and voice data;

if the acquisition is incomplete, sending an acquisition device overhaul alarm and enumerating data items of missing acquired data;

and if the acquisition is complete, determining the working component needing to be started and the power required to be operated according to the acquired data, and generating an analysis result.

2. The intelligent lampblack purifier high-voltage power supply system control method as claimed in claim 1, wherein the sub-step of determining the working components needing to be started and the power needed to be operated according to the collected data is as follows:

acquiring data content of a data item;

determining a working component needing to be started according to the data content, and calling a power meter of the working component;

and calculating to obtain the selected parameters, and determining the required operating power according to the power meter by using the selected parameters.

3. The intelligent lampblack purifier high-voltage power supply system control method as claimed in claim 2, wherein an expression of the calculation selected parameters is as follows:

XY＝BZ×YZ-SJ-GS；

wherein, SJ ═ CG/(HG × y 1);

HG＝U1/y2；

U1＝U2/u；

wherein XY represents the selection parameter; BZ represents the standard oil smoke concentration allowed to be discharged, YZ represents a factor, and the factor is set according to the setting environment and the operation mode of the working component; SJ represents the actual oil smoke concentration collected by the collector; GS represents a preset fixed value; CG is the received feedback light intensity value of the collector; HG is the detection light intensity value sent by the collector; y1 is a first consumption parameter, which is a molecular consumption parameter of the detected light; u1 is the input voltage of the feedback light received by the collector; y2 is a second consumption parameter value, which is a molecular consumption parameter of the feedback light; u2 is the output voltage of the collector sending detection light; u is the voltage gain.

4. The utility model provides an intelligence lampblack purifier high voltage power supply system which characterized in that includes: the device comprises a controller, at least one collector, a plurality of high-voltage power supplies and a plurality of working components; the high-voltage power supplies are connected with the working components in a one-to-one correspondence manner; each high-voltage power supply is in signal connection with the controller; each collector is in signal connection with the controller;

wherein, the controller: the intelligent lampblack purifier high-voltage power supply system control method is used for executing the intelligent lampblack purifier high-voltage power supply system control method according to any one of claims 1 to 3;

a collector: the controller is used for acquiring the acquired data and uploading the acquired data to the controller;

a high-voltage power supply: selecting a working mode according to a working instruction issued by the controller, and providing a working power supply for a corresponding working component;

a working part: and the operation is carried out according to the power supply provided by the high-voltage power supply.

5. The intelligent soot cleaner high-voltage power supply system according to claim 4, wherein the controller comprises: the device comprises a receiving unit, a processing unit, a storage unit and a power supply unit;

wherein the receiving unit: the data acquisition unit is used for receiving the acquired data uploaded by the acquisition unit, analyzing the acquired data, generating an analysis result and uploading the analysis result to the processing unit;

a processing unit: the device is used for receiving the analysis result sent by the receiving unit and selecting a high-voltage power supply to be started and a corresponding working mode according to the analysis result; generating a working instruction for a high-voltage power supply to be started and a corresponding working mode; issuing a working instruction to a high-voltage power supply to be started, and receiving feedback operation information;

a storage unit: the system is used for storing the received collected data and the operation information;

a power supply unit: for powering the receiving unit, the processing unit and the storage unit.

6. The intelligent soot cleaner high-voltage power supply system according to claim 5, wherein the working component comprises a fault alarm.

7. The intelligent lampblack purifier high voltage power supply system as claimed in claim 6, further comprising a backup high voltage power supply; the standby high-voltage power supply is in signal connection with the controller and is respectively connected with each working component.

8. The intelligent soot cleaner high-voltage power supply system according to claim 7, wherein each high-voltage power supply has at least one operation mode.

Images