CN116336529A - Kitchen ventilator installation and debugging method and device - Google Patents

Abstract

The application relates to a method and a device for installing and debugging a range hood, wherein the method comprises the steps of receiving an installation request transmitted by a server, wherein the installation request comprises installation survey information and product parameter information corresponding to the range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range and the smoke exhaust pipe installation position of the range hood to be debugged; generating reference operation data according to product parameter information, installation height, a range hood installation position and a smoke exhaust pipe installation position; the method comprises the steps of obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data to obtain debugged operation data, displaying the debugged operation data through a display device of the range hood to be debugged, realizing debugging and optimizing of the range hood, improving the working performance of the range hood after installation, and realizing that the range hood after installation can be in an optimal working state.

Description

Kitchen ventilator installation and debugging method and device

Technical Field

The application relates to the technical field of kitchen ventilator installation, in particular to a kitchen ventilator installation and debugging method and device.

Background

The fume exhauster is also called fume exhauster or fume exhauster, and is one kind of kitchen appliance for purifying kitchen environment. The range hood is arranged above the kitchen range, can rapidly pump away waste generated in combustion of the range and oil smoke harmful to human bodies in the cooking process, is discharged outdoors, and simultaneously condenses and collects the oil smoke, so that pollution is reduced, air is purified, and the range hood has the effects of gas protection and explosion prevention.

In the implementation process, the inventor finds that at least the following problems exist in the conventional technology: after the existing range hood is installed, the equipment can normally run, so that the quality of the installed range hood is judged completely by the personnel of the installer, and no measures are taken to test the performance of the installed range hood. After the installer installs the range hood, it is often unclear whether the equipment is operating in a better state. If the machine is not installed, the conditions of high running noise, high wind pressure, unsmooth smoke exhaust and the like can be caused, and the normal performance of the range hood is affected.

Disclosure of Invention

Accordingly, it is necessary to provide a method and a device for mounting and debugging a range hood, which can optimally debug the range hood after mounting and improve the working performance of the range hood after mounting, aiming at the problems existing in the conventional range hood mounting.

In a first aspect, the present application provides a method for installing and debugging a range hood, including:

receiving an installation request transmitted by a server, wherein the installation request comprises installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range and the smoke exhaust pipe installation position of the range hood to be debugged;

generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position;

the method comprises the steps of obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged.

Optionally, the reference operation data includes reference device operation data and reference environment detection data;

according to the product parameter information, the installation height, the installation position of the range hood and the installation position of the smoke exhaust pipe, the step of generating the reference operation data corresponding to the range hood to be debugged comprises the following steps:

obtaining reference equipment operation data corresponding to the range hood to be debugged according to the product parameter information;

and obtaining reference environment detection data corresponding to the range hood to be debugged based on the installation height, the range hood installation position and the smoke exhaust pipe installation position.

Optionally, the initial operation data includes initial device operation data and initial environment detection data;

according to the reference operation data, the step of processing the initial operation data to obtain the debugged operation data comprises the following steps:

adjusting initial equipment operation data based on reference equipment operation data and reference environment detection data, and recording current equipment operation data and detecting current environment detection data;

and when the current environment detection data reach the reference environment detection data, confirming the current equipment operation data and the current environment detection data as the debugged operation data.

Optionally, the reference equipment operation data at least comprises a reference fan rotation speed and a reference output power; the reference environment detection data at least comprises a reference temperature detection value and a reference smoke detection value;

the initial equipment operation data at least comprises an initial fan rotating speed and an initial output power; the initial environment detection data includes at least an initial temperature detection value and an initial smoke detection value.

Optionally, the step of displaying the debugged operation data through the display device of the range hood to be debugged includes:

the shooting display device displays the image information of the debugged running data and transmits the image information to the server.

Optionally, the step of receiving the installation request transmitted by the server includes:

starting an APP program corresponding to the range hood to be debugged;

starting a recording function of an APP program, and recording first noise information before the start-up of the range hood to be debugged and second noise information after the start-up of the range hood to be debugged respectively;

the first noise information and the second noise information are transmitted to a server.

Optionally, the step of recording the first noise information before the start-up of the range hood to be debugged and the second noise information after the start-up of the range hood to be debugged respectively includes:

confirming the position which is away from the front preset numerical range of the range hood to be debugged as a preset recording position;

the first noise information before the start-up of the range hood to be debugged and the second noise information after the start-up of the range hood to be debugged are recorded respectively at the preset recording positions.

In a second aspect, the present application provides a range hood installation and debugging device, including:

the request receiving unit is used for receiving an installation request transmitted by the server, wherein the installation request comprises installation survey information and product parameter information corresponding to the range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range and the smoke exhaust pipe installation position of the range hood to be debugged;

the data generation unit is used for generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position;

the device comprises a mounting and debugging unit, a display device and a control unit, wherein the mounting and debugging unit is used for acquiring initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data, obtaining debugged operation data, and displaying the debugged operation data through the display device of the range hood to be debugged.

Optionally, the system further comprises a location sharing unit, wherein the location sharing unit is used for acquiring current geographic location information and transmitting the current geographic location information to the server.

Optionally, the system further comprises a communication unit and a shooting unit, wherein the communication unit is respectively connected with the shooting unit, the request receiving unit and the position sharing unit;

and the shooting unit is used for shooting the image information of the running data after the display device is debugged, and transmitting the image information to the server through the communication unit.

One of the above technical solutions has the following advantages and beneficial effects:

one of the above technical solutions has the following advantages and beneficial effects:

in the method for installing and debugging the range hood, an installation request transmitted by a server is received, wherein the installation request comprises installation survey information and product parameter information corresponding to the range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range and the smoke exhaust pipe installation position of the range hood to be debugged; generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position; the method comprises the steps of obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged to realize debugging optimization of the range hood. According to the method and the device, the reference operation data are generated according to the installation environment and the product parameters of the range hood to be debugged, and then the range hood to be debugged can be optimized and debugged according to the reference operation data, so that the working performance of the range hood after installation is improved, and the range hood after installation can be in the optimal working state.

Drawings

FIG. 1 is a schematic diagram of an application environment of a method for installing and debugging a range hood in one embodiment;

FIG. 2 is a schematic diagram of a first flow chart of a method for installing and debugging a range hood according to one embodiment;

FIG. 3 is a flow chart of the reference operational data generation step in one embodiment;

FIG. 4 is a flow chart of the run data generation step after debugging in one embodiment;

FIG. 5 is a third flow diagram of a method of mounting and debugging a range hood in one embodiment;

FIG. 6 is a first block diagram of a smoke machine installation and debugging device in one embodiment;

fig. 7 is a second block diagram of a range hood installation and adjustment device in one embodiment.

Detailed Description

In order to make the present application solution better understood by those skilled in the art, the following description will be made in detail and with reference to the accompanying drawings in the embodiments of the present application, it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, shall fall within the scope of the present application.

It should be noted that the terms "first," "second," and the like in the description and claims of the present application and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate in order to describe the embodiments of the present application described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In addition, the term "plurality" shall mean two as well as more than two.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The present application will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

The range hood installation and debugging method can be applied to an application environment shown in fig. 1. The processing device may include, among other things, a processor 102 and a memory 104, where the memory 104 may be used to store data such as installation survey information, product parameter information, reference operational data, initial operational data, and post-debug operational data. The processor 102 may be configured to receive an installation request transmitted by a server, where the installation request includes installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range and the smoke exhaust pipe installation position of the range hood to be debugged; generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position; the method comprises the steps of obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged. The processing device may further include a display 106, where the display 106 may display the processed post-debugging operational data and the like via a graphical interface. In one example, the processing device may be, but is not limited to, a cell phone, a notebook computer, or a tablet computer.

In one embodiment, as shown in fig. 2, a method for installing and debugging a range hood is provided, and the method is applied to the processor 102 in fig. 1 for illustration, and includes the following steps:

step S210, acquiring an installation request transmitted by a receiving server, wherein the installation request comprises installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range, and the smoke exhaust pipe installation position of the range hood to be debugged.

The server can be used for generating an installation single number corresponding to the installation service of the range hood, distributing corresponding installers according to the installation single number of the range hood, and further generating an installer identification number corresponding to the installers; the server can also generate equipment identification numbers corresponding to the range hoods according to the range hoods selected by the installer. It should be noted that the installation unit number corresponds to a unique installer identification number and equipment identification number. For example, the installation request may include an installation order number, and the installer may establish a relationship with the installation unit according to the installation order number assigned by the server, after confirming the match, with the installer identification number of the corresponding installer. Further, the installer can determine the product model of the range hood according to the installation survey information corresponding to the installation single number, obtain the equipment identification number according to the product model of the range hood, and further establish the corresponding relation among the installation single number, the installer identification number and the equipment identification number, so that the installer can install the selected range hood according to the installation single number and the equipment identification number.

The installation survey information refers to survey information obtained by collecting installation environments of an area to be installed (such as an area to be installed of a kitchen) by a survey staff. For example, the kitchen installation survey information at least includes an installation height of the range hood to be debugged from the kitchen range surface, a range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range, and a smoke exhaust pipe installation position of the range hood to be debugged. The product parameter information may include information such as a product model number, a product size, and a product power parameter of the range hood.

The processor may receive the installation request transmitted by the server, and analyze the installation request, so as to obtain installation survey information and product parameter information corresponding to the range hood to be debugged. Furthermore, the installation survey information and the product parameter information corresponding to the range hood to be debugged can be displayed through the display, so that a debugger can check the installation survey information and the product parameter information.

Step S220, generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position.

The mounting height refers to the mounting height of the range hood to be debugged from the range surface, the mounting position of the range hood refers to the mounting position of the range hood relative to the range hood of the range, and the mounting position of the smoke exhaust pipe refers to the mounting position of the smoke exhaust pipe corresponding to the range hood to be debugged.

The processor can process the product parameter information, the installation height, the installation position of the range hood and the installation position of the smoke exhaust pipe, calculate the optimal operation parameters required by the range hood to be debugged, and further obtain the reference operation data of the range hood to be debugged. For example, according to the product parameter information, a power output range, an output fan rotating speed range and the like corresponding to the range hood to be debugged can be obtained; based on the power output range and the output fan rotating speed range, the installation height, the mounting position of the range hood and the mounting position of the smoke exhaust pipe are processed, so that the optimal output power and the optimal fan rotating speed corresponding to the range hood to be debugged can be obtained. For example, the optimal output power includes a minimum output power and a maximum output power, and the optimal fan speed includes a minimum fan speed and a maximum fan speed.

Step S230, obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to the reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged.

The initial operation data refer to operation data of factory default settings of the range hood to be debugged. For example, the initial operation data may be stored in a server, and the processor may query and obtain the initial operation data corresponding to the range hood to be debugged according to the equipment identification number corresponding to the range hood to be debugged. For another example, the initial operation data may be stored in the range hood to be debugged, and the initial operation data of the range hood to be debugged may be displayed through the display device under the condition that a specific key is triggered. The display device of the range hood to be debugged can be a nixie tube display screen or a liquid crystal display screen. The initial operating data may be, but is not limited to, fan speed, output power, temperature values, and equipment operating status indication information, etc.

The processor can acquire initial operation data corresponding to the range hood to be debugged, and process the initial operation data based on the parameter operation data, so as to obtain the operation data after debugging. Furthermore, the operation data after the debugging obtained through processing can be transmitted to a display device of the range hood to be debugged, and the operation data after the debugging is displayed through the display device, so that the debugging optimization of the range hood is realized.

In the above embodiment, the installation request transmitted by the server is received, and the installation request is analyzed, so that product parameter information, the installation height of the range hood to be debugged from the range surface, the installation position of the range hood to be debugged on the range hood installation surface relative to the range hood and the installation position of the smoke exhaust pipe of the range hood to be debugged are obtained; generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position; the method comprises the steps of obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged to realize debugging optimization of the range hood. According to the method and the device, the reference operation data are generated according to the installation environment and the product parameters of the range hood to be debugged, and then the range hood to be debugged can be optimized and debugged according to the reference operation data, so that the working performance of the range hood after installation is improved, and the range hood after installation can be in the optimal working state.

In one embodiment, as shown in FIG. 3, the reference operational data includes reference device operational data and reference environment detection data. According to the product parameter information, the installation height, the installation position of the range hood and the installation position of the smoke exhaust pipe, the step of generating the reference operation data corresponding to the range hood to be debugged comprises the following steps:

step S310, obtaining the reference equipment operation data corresponding to the range hood to be debugged according to the product parameter information.

The reference equipment operation data at least comprises a reference fan rotating speed and a reference output power; the reference fan speed may be a fan speed range value and the reference output power may be an output power range value. The processor can analyze and process the product parameter information, and further obtain reference equipment operation data corresponding to the range hood to be debugged. For example, a fan rotating speed range value and an output power range value corresponding to the range hood to be debugged can be obtained according to product parameter information, and then corresponding reference equipment operation data is obtained.

Step S320, obtaining reference environment detection data corresponding to the range hood to be debugged based on the installation height, the installation position of the range hood and the installation position of the smoke exhaust pipe.

Wherein the reference environment detection data comprises at least a reference temperature detection value and a reference smoke detection value; the reference temperature detection value may be a temperature range value and the reference smoke detection value may be a smoke range value. The method comprises the steps of measuring and calculating the space size of generated smoke according to the installation height, the installation position of the range hood and the installation position of the smoke exhaust pipe, and further determining the reference environment detection data corresponding to the range hood to be debugged according to the space size of generated smoke. The reference smoke detection value may be a reference PM2.5 detection value.

In one embodiment, as shown in FIG. 4, the initial operational data includes initial device operational data and initial environment detection data. According to the reference operation data, the step of processing the initial operation data to obtain the debugged operation data comprises the following steps:

step S410, based on the reference device operation data and the reference environment detection data, adjusts the initial device operation data, and records the current device operation data and detects the current environment detection data.

The initial equipment operation data at least comprises an initial fan rotating speed and an initial output power; the initial fan rotating speed and the initial output power are data of factory default settings of the range hood. The initial environment detection data at least comprises an initial temperature detection value and an initial smoke detection value; the initial temperature detection value and the initial smoke detection value are data of factory default settings of the range hood. The initial smoke detection value may be an initial PM2.5 detection value.

The range hood to be debugged and the smoke generating device are started, initial equipment operation data are adjusted based on reference equipment operation data and reference environment detection data, and current equipment operation data and current environment detection data are recorded.

Step S420, when the current environment detection data reaches the reference environment detection data, the current device operation data and the current environment detection data are confirmed to be the debugged operation data.

And judging the detected current environment detection data, and judging that the range hood to be debugged is in an optimal running state when the current environment detection data reach the reference environment detection data, so as to confirm the current equipment running data and the current environment detection data as the debugged running data. Furthermore, the display device of the range hood to be debugged can display the debugged running data, so that the range hood can be debugged and optimized.

In the above embodiment, the device operation data and the environment detection data of the range hood to be debugged are matched and optimized to obtain the debugged operation data, so that the range hood to be debugged can be in an optimal operation state, the working performance of the range hood after installation is improved, and the range hood after installation can be in an optimal working state.

In one embodiment, as shown in fig. 5, a method for installing and debugging a range hood is provided, and the method is applied to the processor 102 in fig. 1 for illustration, and includes the following steps:

step S510, obtaining an installation request transmitted by a receiving server, wherein the installation request comprises installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range, and the smoke exhaust pipe installation position of the range hood to be debugged.

The specific description of step S510 is referred to the description of the above embodiments, and is not repeated here.

Step S520, generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position.

The specific description of step S520 is referred to the description of the above embodiments, and is not repeated here.

Step S530, obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to the reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged.

The specific description of the step S530 is referred to the description of the above embodiments, and is not repeated here.

In step S540, the photographing display device displays the image information of the debugged operation data, and transmits the image information to the server.

The processing equipment can further comprise a camera unit, the camera unit can shoot image information of the running data after debugging, the display device is displayed, the image information is transmitted to the server, and then the server can judge the debugging completion condition of the range hood to be debugged according to the image information. The server can also evaluate the work completion of the corresponding debugging personnel according to the image information. In addition, the server can store the image information in a history database as history data corresponding to the range hoods to be debugged, so that the history data can be directly called for subsequent debugging of the range hoods of corresponding models, and further the debugging efficiency is improved.

In the above embodiment, the reference operation data is generated according to the installation environment and the product parameters of the range hood to be debugged, so that the range hood to be debugged can be optimized and debugged according to the reference operation data, the working performance of the range hood after being installed is improved, and the range hood after being installed can be in the optimal working state. The image information of the running data after debugging is displayed by the display device is shot and uploaded to the server, so that the debugging completion condition of the range hood to be debugged is judged, the work completion condition of corresponding debugging personnel is checked and evaluated, the range hood of corresponding model can be conveniently and directly debugged, historical data can be directly called, and the debugging efficiency is improved.

In one embodiment, the step of receiving the server-transmitted installation request includes, after:

starting an APP program corresponding to the range hood to be debugged; starting a recording function of an APP program, and recording first noise information before the start-up of the range hood to be debugged and second noise information after the start-up of the range hood to be debugged respectively; the first noise information and the second noise information are transmitted to a server.

Wherein the APP program can be pre-installed in the processing equipment, the processing equipment further comprises a recording module, a debugger can start the APP program corresponding to the range hood to be debugged by operating the processing equipment, the recording module is started, the recording function of the APP program is started,

recording first noise information of the range hood to be debugged before starting up, and recording the first noise information as background sound. Recording second noise of the range hood to be debugged after being started, transmitting the first noise information and the second noise information to a server, and further, the server can judge whether the first noise information and the second noise information meet requirements according to the processing of the first noise information and the second noise information, if so, the noise of the range hood to be debugged is judged to be qualified, and if not, the noise of the range hood to be debugged is judged to be unqualified.

In one example, the step of recording the first noise information before the start-up of the range hood to be debugged and the second noise information after the start-up of the range hood to be debugged respectively includes:

confirming the position which is away from the front preset numerical range of the range hood to be debugged as a preset recording position; the first noise information before the start-up of the range hood to be debugged and the second noise information after the start-up of the range hood to be debugged are recorded respectively at the preset recording positions.

The front preset value range may be determined according to an actual installation space, and may be set to 0.5 to 1.5 meters, for example. The first noise information before the start of the range hood to be debugged and the second noise information after the start of the range hood to be debugged are recorded at the preset recording position, the first noise information and the second noise information are transmitted to the server, and the accuracy of recording the first noise information and the second noise information is improved.

In one example, the processing device is further configured to obtain current geographic location information, and transmit the current geographic location information to a server, so as to implement real-time positioning of the debug person.

It should be understood that, although the steps in the flowcharts of fig. 2-5 are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least some of the steps of fig. 2-5 may include multiple sub-steps or stages that are not necessarily performed at the same time, but may be performed at different times, nor do the order in which the sub-steps or stages are performed necessarily occur sequentially, but may be performed alternately or alternately with at least a portion of the sub-steps or stages of other steps or other steps.

In one embodiment, as shown in fig. 6, there is provided a range hood installation and debugging device, including:

a request receiving unit 610, configured to receive an installation request transmitted by a server, where the installation request includes installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range, and the smoke exhaust pipe installation position of the range hood to be debugged.

The data generating unit 620 is configured to generate reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position.

The installation and debugging unit 630 is configured to obtain initial operation data corresponding to the range hood to be debugged, process the initial operation data according to the reference operation data, obtain the debugged operation data, and display the debugged operation data through a display device of the range hood to be debugged.

Among them, the request receiving unit 610 is connected to the data generating unit 620, and the data generating unit 620 is connected to the installation debugging unit 630. The request receiving unit 610 analyzes the installation request by receiving the installation request transmitted by the server, so as to obtain product parameter information, the installation height of the range hood to be debugged from the range surface, the installation position of the range hood to be debugged on the range hood installation surface relative to the range hood and the installation position of the smoke exhaust pipe of the range hood to be debugged; the data generating unit 620 generates reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position; the installation and debugging unit 630 obtains initial operation data corresponding to the range hood to be debugged, processes the initial operation data according to the reference operation data to obtain debugged operation data, and displays the debugged operation data through a display device of the range hood to be debugged to realize the debugging optimization of the range hood.

In the above embodiment, the data generating unit 620 is connected between the request receiving unit 610 and the installation and debugging unit 630, and generates the reference operation data according to the installation environment and the product parameters of the range hood to be debugged, so that the range hood to be debugged can be optimized according to the reference operation data, the working performance of the range hood after installation is improved, and the range hood after installation can be in the optimal working state.

In one example, as shown in fig. 7, the range hood installation and debugging device further includes a location sharing unit 640, where the location sharing unit 640 is configured to obtain current geographical location information, and transmit the current geographical location information to the server.

The location sharing unit 640 may include a positioning module, through which the current location of the range hood installation and debugging device may be positioned in real time. The current geographic position information is acquired through the position sharing unit 640 and is transmitted to the server, so that the real-time positioning of the personnel to be tested is realized, and the server can monitor the position of the personnel to be tested.

In one example, as shown in fig. 7, the range hood installation and debugging device further includes a communication unit 650 and a photographing unit 660, wherein the communication unit 650 is respectively connected with the photographing unit 660, the request receiving unit 610, and the location sharing unit 640; and a photographing unit 660 for photographing image information of the display device displaying the debugged operation data and transmitting the image information to the server through the communication unit.

Wherein the communication unit 650 may be a long-range communication module or a short-range communication module, for example, the long-range communication module may be, but is not limited to, an ethernet communication module and a GPRS communication module. The short-range communication module may be, but is not limited to, a WIFI communication module and a bluetooth communication module. The shooting unit 660 may include a camera, through which the display device may display the debugged operation data to shoot, thereby obtaining image information.

Based on the communication unit 650 connecting the request receiving unit 610, the request receiving unit 610 may then establish a connection with a server through the communication unit 650, and the server may transmit an installation request to the request receiving unit 610 through the communication unit 650. Based on the communication unit 650 connecting the location sharing unit 640, and thus the location sharing unit 640 establishes a connection with the server through the communication unit 650, the location sharing unit 640 may transmit the current geographical location information to the server through the communication unit 650. The camera unit 660 is connected based on the communication unit 650, and then the camera unit 660 is connected with the server through the communication unit 650, the camera unit 660 shoots the image information of the running data after the display device is displayed and debugged, and transmits the image information to the server through the communication unit 650, and the image information of the running data after the display device is displayed and debugged is shot and uploaded to the server, so that the debugging completion condition of the range hood to be debugged and the corresponding work completion condition of a debugger are judged, in addition, the range hood with the corresponding model can be conveniently debugged in a follow-up mode, historical data can be directly called, and the debugging efficiency is improved.

The specific limitation of the range hood installation and debugging device can be referred to the limitation of the range hood installation and debugging method, and the description thereof is omitted here. All or part of the modules in the kitchen ventilator installation and debugging device can be realized by software, hardware and a combination thereof.

It will be appreciated by those skilled in the art that the structures shown in fig. 6-7 are block diagrams of only some of the structures associated with the present application and are not intended to limit the range hood mounting adjustment device to which the present application is applied, and that a particular range hood mounting adjustment device may include more or fewer components than shown, or may incorporate certain components, or may have a different arrangement of components.

In one embodiment, the present application provides a computer storage medium having a computer program stored thereon, which when executed by a processor, implements the steps of the range hood installation debugging method of any one of the above.

In one example, the computer program when executed by a processor performs the steps of:

receiving an installation request transmitted by a server, wherein the installation request comprises installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the kitchen range surface, the range hood installation position of the range hood to be debugged on the range hood installation surface relative to the kitchen range and the smoke exhaust pipe installation position of the range hood to be debugged; generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position; the method comprises the steps of obtaining initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged.

Those skilled in the art will appreciate that implementing all or part of the above-described embodiments of the method may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of embodiments of the division methods described above. Any reference to memory, storage, database, or other medium used in the various embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples only represent a few embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the claims. It should be noted that it would be apparent to those skilled in the art that various modifications and improvements could be made without departing from the spirit of the present application, which would be within the scope of the present application. Accordingly, the scope of protection of the present application is to be determined by the claims appended hereto.

Claims (10)

1. The method for installing and debugging the range hood is characterized by comprising the following steps of:

receiving an installation request transmitted by a server, wherein the installation request comprises installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the range surface, the range hood installation position of the range hood to be debugged relative to the range on the range hood installation surface and the smoke exhaust pipe installation position of the range hood to be debugged;

generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the smoke exhaust pipe installation position;

acquiring initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to the reference operation data to obtain debugged operation data, and displaying the debugged operation data through a display device of the range hood to be debugged.

2. The range hood installation and debugging method according to claim 1, wherein the reference operation data includes reference equipment operation data and reference environment detection data;

the step of generating the reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the fume exhaust pipe installation position comprises the following steps:

obtaining the reference equipment operation data corresponding to the range hood to be debugged according to the product parameter information;

and obtaining the reference environment detection data corresponding to the range hood to be debugged based on the mounting height, the range hood mounting position and the fume exhaust pipe mounting position.

3. The range hood installation and debugging method according to claim 2, wherein the initial operation data includes initial equipment operation data and initial environment detection data;

the step of processing the initial operation data according to the reference operation data to obtain the debugged operation data comprises the following steps:

adjusting the initial equipment operation data based on the reference equipment operation data and the reference environment detection data, and recording current equipment operation data and detecting current environment detection data;

and when the current environment detection data reach the reference environment detection data, confirming the current equipment operation data and the current environment detection data as the debugged operation data.

4. The range hood installation and debugging method according to claim 3, wherein the reference equipment operation data at least comprises a reference fan rotation speed and a reference output power; the reference environment detection data at least comprises a reference temperature detection value and a reference smoke detection value;

the initial equipment operation data at least comprises an initial fan rotating speed and an initial output power; the initial environment detection data includes at least an initial temperature detection value and an initial smoke detection value.

5. The method for installing and debugging a range hood according to claim 1, wherein the step of displaying the debugged operation data by the display device of the range hood to be debugged comprises:

and shooting the image information of the display device for displaying the debugged running data, and transmitting the image information to the server.

6. The range hood installation and debugging method according to any one of claims 1 to 5, wherein the step of receiving the installation request transmitted by the server comprises:

starting an APP program corresponding to the range hood to be debugged;

starting a recording function of the APP program, and recording first noise information before the start-up of the range hood to be debugged and second noise information after the start-up of the range hood to be debugged respectively;

transmitting the first noise information and the second noise information to the server.

7. The method for installing and debugging a range hood according to claim 6, wherein the step of recording the first noise information before the start-up of the range hood to be debugged and the second noise information after the start-up of the range hood to be debugged respectively includes:

confirming the position which is away from the front preset numerical range of the range hood to be debugged as a preset recording position;

and the first noise information before the start of the range hood to be debugged and the second noise information after the start of the range hood to be debugged are recorded respectively at the preset recording positions.

8. The utility model provides a lampblack absorber installation debugging device which characterized in that includes:

the system comprises a request receiving unit, a server and a debugging unit, wherein the request receiving unit is used for receiving an installation request transmitted by the server, and the installation request comprises installation survey information and product parameter information corresponding to a range hood to be debugged; the installation survey information at least comprises the installation height of the range hood to be debugged from the range surface, the range hood installation position of the range hood to be debugged relative to the range on the range hood installation surface and the smoke exhaust pipe installation position of the range hood to be debugged;

the data generation unit is used for generating reference operation data corresponding to the range hood to be debugged according to the product parameter information, the installation height, the range hood installation position and the fume exhaust pipe installation position;

the installation and debugging unit is used for acquiring initial operation data corresponding to the range hood to be debugged, processing the initial operation data according to the reference operation data to obtain debugged operation data, and displaying the debugged operation data through the display device of the range hood to be debugged.

9. The range hood installation and debugging device according to claim 8, further comprising a location sharing unit, wherein the location sharing unit is configured to obtain current geographic location information, and transmit the current geographic location information to the server.

10. The range hood installation and debugging device according to claim 9, further comprising a communication unit and a shooting unit, wherein the communication unit is respectively connected with the shooting unit, the request receiving unit and the position sharing unit;

the shooting unit is used for shooting the image information of the running data after debugging displayed by the display device and transmitting the image information to the server through the communication unit.

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