Summary of the invention
The disclosure provides the acquisition methods and device of a kind of tin oxide electrode push-in stroke, to solve the pool wall of glass furnace
After brick is etched, tin oxide electrode push-in stroke leads to the problem of deviation.
To achieve the goals above, according to the first aspect of the embodiments of the present disclosure, a kind of tin oxide electrode push-in stroke is provided
Acquisition methods, be applied to glass furnace, which is characterized in that the glass furnace includes tin oxide electrode and tank block, described
Method includes:
According to the introduction volume of tin oxide in raw material, the discharge of the glass furnace tin oxide, tin oxide volatile quantity
Obtain the erosion amount of the tin oxide electrode;
According to the discharge of the zirconium oxide, the erosion amount of the tank block is obtained;
According to the erosion amount of the erosion amount of the tin oxide electrode and the tank block, it is opposite to obtain the tin oxide electrode
In the push-in stroke of the tank block.
Optionally, the tin oxide electrode is N group tin oxide electrode, and the glass furnace is according to the N group tin oxide electricity
Pole is divided into N number of area, and wherein N is positive integer;
It is described to be waved according to the introduction volume of tin oxide in raw material, the discharge of the glass furnace tin oxide, tin oxide
Hair amount obtains the erosion amount of the tin oxide electrode, comprising:
According to the introduction volume of the tin oxide, the discharge of the tin oxide, the tin oxide volatile quantity and the N
The erosion of electrode proportionality coefficient in each area in a area obtains the tin oxide electrode erosion amount in each area;
The discharge according to the zirconium oxide, obtains the erosion amount of the tank block, comprising:
Ratio system is corroded according to the tank block in each area in the discharge of the glass furnace zirconium oxide and N number of area
Number obtains the tank block erosion amount in each area;
It is described according to the erosion amount of the tin oxide electrode and the erosion amount of the tank block, obtain the tin oxide electrode
Push-in stroke relative to the tank block, comprising:
According to the tank block erosion amount of the tin oxide electrode erosion amount in each area and each area, obtain described every
Push-in stroke of the tin oxide electrode in a area relative to the tank block in the region.
Optionally, the volatilization of the introduction volume, the discharge, the tin oxide of the tin oxide according to the tin oxide
The erosion of electrode proportionality coefficient in each area in amount and N number of area obtains the tin oxide electrode erosion amount in each area, packet
It includes:
According to the volatile quantity of the introduction volume of the tin oxide, the discharge of the tin oxide and the tin oxide, institute is obtained
State the total amount of erosion of tin oxide electrode group;
According to the erosion of electrode ratio system in each area in the total amount of erosion of the tin oxide electrode group and N number of area
Number obtains the tin oxide electrode erosion amount in each area.
Optionally, the tank block according to each area in the discharge of the glass furnace zirconium oxide and N number of area
Proportionality coefficient is corroded, the tank block erosion amount in each area is obtained, comprising:
According to the discharge of the zirconium oxide, the total amount of erosion of the tank block is obtained;
Proportionality coefficient is corroded according to the tank block in each area in the total amount of erosion of the tank block and N number of area, is obtained
Take the tank block erosion amount in each area.
Optionally, the introduction volume, the discharge of the tin oxide and waving for the tin oxide according to the tin oxide
Hair amount obtains the total amount of erosion of the tin oxide electrode group, comprising:
According to the volatile quantity of the introduction volume of the tin oxide, the discharge of the tin oxide and the tin oxide, using pre-
If electrode total amount of erosion algorithm obtain the total amount of erosion of the tin oxide electrode group;
Wherein, the preset electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerIndicate the total amount of erosion of the tin oxide electrode group, SnoutIndicate the discharge of the tin oxide,
SnvolIndicate the volatile quantity of the tin oxide, SninIndicate the introduction volume of the tin oxide;
The erosion of electrode ratio according to each area in the total amount of erosion of the tin oxide electrode group and N number of area
Example coefficient, obtains the tin oxide electrode erosion amount in each area, comprising:
According to the erosion of electrode ratio system in each area in the total amount of erosion of the tin oxide electrode group and N number of area
Number corrodes quantity algorithm using preset area electrodes, obtains the tin oxide electrode erosion amount in each area;
The preset area electrodes corrode quantity algorithm
Wherein, SniIndicate that the tin oxide electrode erosion amount in i-th of area, D indicate the total cross-sectional area of tin oxide electrode, kiTable
Show i-th of area erosion of electrode proportionality coefficient, 1≤i≤N.
Optionally, the discharge according to the zirconium oxide, the total amount of erosion for obtaining the tank block include:
The tank block is obtained using preset tank block total amount of erosion algorithm according to the discharge of the zirconium oxide
Total amount of erosion;
Wherein, the preset tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerIndicate the total amount of erosion of the tank block, ZroutIndicate the discharge of the glass furnace zirconium oxide;
The tank block according to each area in the total amount of erosion of the tank block and N number of area corrodes ratio system
Number obtains the tank block erosion amount in each area, comprising:
Proportionality coefficient, benefit are corroded according to the tank block in each area in the total amount of erosion of the tank block and N number of area
With preset region tank block erosion amount algorithm, the tank block erosion amount in each area is obtained;
Wherein, the preset region tank block erosion amount algorithm includes:
Wherein, ZriIndicate that the tank block erosion amount in i-th of area, F indicate the total surface area of tank block, jiIndicate described i-th
The tank block in a area corrodes proportionality coefficient, 1≤i≤N.
Optionally, described to be corroded according to the tin oxide electrode erosion amount in each area and the tank block in each area
Amount obtains the push-in stroke of tank block of the tin oxide electrode in each area relative to the region, comprising:
According to the tank block erosion amount of the erosion of electrode amount in each area and each area, preset push-in stroke is utilized
Algorithm obtains the push-in stroke of tank block of the tin oxide electrode in each area relative to the region;
Wherein, the preset propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiIndicate the push-in stroke of the tin oxide electrode in i-th of area relative to the tank block in i-th of area, SniTable
Show the tin oxide electrode erosion amount in i-th of area, ZriIndicate the tank block erosion amount in i-th of area, 1≤i≤N.
According to the second aspect of an embodiment of the present disclosure, a kind of acquisition device of tin oxide electrode push-in stroke is provided, is applied to
Glass furnace, which is characterized in that the glass furnace includes tin oxide electrode and tank block, and described device includes: the first erosion
Amount obtains module, the second erosion amount obtains module and push-in stroke obtains module;
First erosion amount obtains module, for according to the introduction volume of tin oxide, the glass furnace oxygen in raw material
The volatile quantity of the discharge, tin oxide of changing tin obtains the erosion amount of the tin oxide electrode;
Second erosion amount obtains module and obtains invading for the tank block for the discharge according to the zirconium oxide
Erosion amount;
The push-in stroke obtains module, for the erosion according to the erosion amount and the tank block of the tin oxide electrode
Amount, obtains push-in stroke of the tin oxide electrode relative to the tank block.
Optionally, the tin oxide electrode is N group tin oxide electrode, and the glass furnace is according to the N group tin oxide electricity
Pole is divided into N number of area, and wherein N is positive integer;
First erosion amount obtains module, for according to the introduction volume of the tin oxide, the discharge of the tin oxide,
The erosion of electrode proportionality coefficient in each area in the volatile quantity of the tin oxide and N number of area obtains the oxygen in each area
Change tin electrode erosion amount;
Second erosion amount obtains module, for according to the glass furnace zirconium oxide discharge and N number of area
In the tank block in each area corrode proportionality coefficient, obtain the tank block erosion amount in each area;
The push-in stroke obtains module, for according to the tin oxide electrode erosion amount in each area and each area
Tank block erosion amount obtains the push-in stroke of tank block of the tin oxide electrode in each area relative to the region.
Optionally, it includes: that the first total amount of erosion acquisition submodule and first area are invaded that first erosion amount, which obtains module,
Erosion amount acquisition submodule;
The first total amount of erosion acquisition submodule, for the stream according to the introduction volume of the tin oxide, the tin oxide
The volatile quantity of output and the tin oxide obtains the total amount of erosion of the tin oxide electrode group;
The first area erosion amount acquisition submodule, for the total amount of erosion according to the tin oxide electrode group, and
The erosion of electrode proportionality coefficient in each area in N number of area obtains the tin oxide electrode erosion amount in each area.
Optionally, it includes: that the second total amount of erosion acquisition submodule and second area are invaded that second erosion amount, which obtains module,
Erosion amount acquisition submodule;
The second total amount of erosion acquisition submodule obtains the tank block for the discharge according to the zirconium oxide
Total amount of erosion;
The second area erosion amount acquisition submodule, for according to the total amount of erosion of the tank block and described N number of
The tank block in each area corrodes proportionality coefficient in area, obtains the tank block erosion amount in each area.
Optionally, the first total amount of erosion acquisition submodule is used for:
According to the volatile quantity of the introduction volume of the tin oxide, the discharge of the tin oxide and the tin oxide, using pre-
If electrode total amount of erosion algorithm obtain the total amount of erosion of the tin oxide electrode group;
Wherein, the preset electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerIndicate the total amount of erosion of the tin oxide electrode group, SnoutIndicate the discharge of the tin oxide,
SnvolIndicate the volatile quantity of the tin oxide, SninIndicate the introduction volume of the tin oxide;
The first area erosion amount acquisition submodule is used for:
According to the erosion of electrode ratio system in each area in the total amount of erosion of the tin oxide electrode group and N number of area
Number corrodes quantity algorithm using preset area electrodes, obtains the tin oxide electrode erosion amount in each area;
The preset area electrodes corrode quantity algorithm
Wherein, SniIndicate that the tin oxide electrode erosion amount in i-th of area, D indicate the total cross-sectional area of tin oxide electrode, kiTable
Show i-th of area erosion of electrode proportionality coefficient, 1≤i≤N.
Optionally, the second total amount of erosion acquisition submodule is used for:
The tank block is obtained using preset tank block total amount of erosion algorithm according to the discharge of the zirconium oxide
Total amount of erosion;
Wherein, the preset tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerIndicate the total amount of erosion of the tank block, ZroutIndicate the discharge of the glass furnace zirconium oxide;
The second area erosion amount acquisition submodule is used for:
Proportionality coefficient, benefit are corroded according to the tank block in each area in the total amount of erosion of the tank block and N number of area
With preset region tank block erosion amount algorithm, the tank block erosion amount in each area is obtained;
Wherein, the preset region tank block erosion amount algorithm includes:
Wherein, ZriIndicate that the tank block erosion amount in i-th of area, F indicate the total surface area of tank block, jiIndicate described i-th
The tank block in a area corrodes proportionality coefficient, 1≤i≤N.
Optionally, the push-in stroke obtains module and is used for:
According to the tank block erosion amount of the erosion of electrode amount in each area and each area, preset push-in stroke is utilized
Algorithm obtains the push-in stroke of tank block of the tin oxide electrode in each area relative to the region;
Wherein, the preset propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiIndicate the push-in stroke of the tin oxide electrode in i-th of area relative to the tank block in i-th of area, SniTable
Show the tin oxide electrode erosion amount in i-th of area, ZriIndicate the tank block erosion amount in i-th of area, 1≤i≤N.
Through the above technical solutions, the disclosure obtains glass cellar by the introduction volume, discharge and volatile quantity of tin oxide
The erosion amount of tin oxide electrode in furnace obtains the erosion amount of tank block by the discharge of zirconium oxide, and combines tin oxide electricity
The erosion amount of the erosion amount of pole and tank block obtains push-in stroke of the tin oxide electrode relative to tank block, is able to solve glass furnace
After the tank block of furnace is etched, tin oxide electrode push-in stroke leads to the problem of deviation, and tin oxide electrode and tank block is made to keep flat
Together, the working efficiency of glass furnace is improved.
It should be understood that above general description and following detailed description be only it is exemplary and explanatory, not
The disclosure can be limited.
Specific embodiment
Example embodiments are described in detail here, and the example is illustrated in the accompanying drawings.Following description is related to
When attached drawing, unless otherwise indicated, the same numbers in different drawings indicate the same or similar elements.Following exemplary embodiment
Described in embodiment do not represent all implementations consistent with this disclosure.On the contrary, they be only with it is such as appended
The example of the consistent device and method of some aspects be described in detail in claims, the disclosure.
It is each to the disclosure first before the acquisition methods and device of tin oxide electrode push-in stroke of disclosure offer are provided
Application scenarios involved by a embodiment are introduced.The application scenarios are to manufacture glass using glass furnace heating raw materials,
The structure of glass furnace can be divided into three parts: tin oxide electrode, tank block and bottom of pond brick.Wherein tin oxide electrode can divide
For multiple groups tin oxide electrode.
Fig. 1 is a kind of acquisition methods flow chart of tin oxide electrode push-in stroke shown according to an exemplary embodiment, such as
Shown in Fig. 1, this method is applied to glass furnace, which includes tin oxide electrode and tank block, comprising:
Step 101, it is waved according to the introduction volume of tin oxide in raw material, the discharge of glass furnace tin oxide, tin oxide
The erosion amount of hair amount acquisition tin oxide electrode.
It should be noted that including tin oxide in the raw material of glass furnace fusing, can add according in glass furnace
The quality and tin oxide of the raw material entered ratio shared in raw material, to obtain the introduction volume of tin oxide in raw material.Glass
The discharge of glass kiln tin oxide can be obtained measuring the content of tin oxide in glass substrate made of glass furnace.And
The volatile quantity of tin oxide refers to the scaling loss amount of glass furnace tin oxide when manufacturing glass substrate, can be according in glass furnace
The quality and tin oxide of gas ratio shared in the gas obtains.
Step 102, according to the discharge of zirconium oxide, the erosion amount of tank block is obtained.
Exemplary, in the manufacturing process of glass substrate, tank block can be also etched, so that the glass that glass furnace produces
Include zirconium oxide in glass substrate, therefore can be obtained measuring the content of zirconium oxide in glass substrate made of glass furnace
The erosion amount of tank block.
Step 103, according to the erosion amount of the erosion amount of tin oxide electrode and tank block, tin oxide electrode is obtained relative to pond
The push-in stroke of nogging.
For example, according to the difference between the erosion amount of tin oxide electrode and the erosion amount of tank block obtained in first two
Value, it will be able to push-in stroke of the tin oxide electrode relative to tank block is obtained, with push-in stroke adjustment tin oxide electrode in glass furnace
Position in furnace can make tin oxide electrode remain concordant with tank block.
The tin oxide electrode of usual glass furnace is multi-group electrode, therefore is N group tin oxide electrode, glass in tin oxide electrode
Glass kiln is divided into N number of area according to N group tin oxide electrode, this is because the tin oxide electrode and pool wall of glass furnace different zones
The erosion amount of brick may be different, therefore glass furnace can be divided into multiple regions according to the position where each group electrode,
In the case of this:
Step 101 includes: according to the introduction volume of tin oxide, the discharge of tin oxide, the volatile quantity of tin oxide and N number of area
In each area erosion of electrode proportionality coefficient, obtain the tin oxide electrode erosion amount in each area.
Step 102 includes: to corrode ratio according to the tank block in each area in the discharge of glass furnace zirconium oxide and N number of area
Coefficient obtains the tank block erosion amount in each area.
Step 103 includes: the tank block erosion amount of the tin oxide electrode erosion amount and each area according to each area, is obtained every
Push-in stroke of the tin oxide electrode in a area relative to the tank block in the region.
It should be noted that contact area of the N group tin oxide electrode in glass furnace can be different, therefore each group
The corresponding push-in stroke of tin oxide electrode is also different.Glass furnace is divided into N number of area according to N group tin oxide electrode, it is N number of
Area respectively corresponds the tank block in N number of area.Therefore can be obtained according to the division in N number of area each area tin oxide electrode erosion amount and
Tank block erosion amount, and the push-in stroke of the tin oxide electrode in each area relative to the tank block in the region is obtained with this.With N number of area
Corresponding push-in stroke adjusts corresponding position of N number of tin oxide electrode in glass furnace, makes N number of tin oxide electrode can be with
Tank block remains concordant.
Fig. 2 is the acquisition methods flow chart of another tin oxide electrode push-in stroke shown according to an exemplary embodiment,
As shown in Fig. 2, step 101 includes:
Step 1011, according to the volatile quantity of the introduction volume of tin oxide, the discharge of tin oxide and tin oxide, tin oxide is obtained
The total amount of erosion of electrode group.
The step can be according to the volatile quantity of the introduction volume of tin oxide, the discharge of tin oxide and tin oxide, using default
Electrode total amount of erosion algorithm obtain tin oxide electrode group total amount of erosion.
Wherein, preset electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerIndicate the total amount of erosion of tin oxide electrode group, SnoutIndicate the discharge of tin oxide, SnvolIndicate oxygen
Change the volatile quantity of tin, SninIndicate the introduction volume of tin oxide.
Step 1012, according to the erosion of electrode ratio system in each area in the total amount of erosion of tin oxide electrode group and N number of area
Number, obtains the tin oxide electrode erosion amount in each area.
The step can be according to the erosion of electrode ratio system in each area in the total amount of erosion of tin oxide electrode group and N number of area
Number corrodes quantity algorithm using preset area electrodes, obtains the tin oxide electrode erosion amount in each area.
Preset area electrodes corrode quantity algorithm
Wherein, SniIndicate that the tin oxide electrode erosion amount in i-th of area, D indicate the total cross-sectional area of tin oxide electrode, kiTable
Show i-th of area's erosion of electrode proportionality coefficient, 1≤i≤N.Wherein, here the total cross-sectional area of tin oxide electrode refers to above-mentioned
The total cross-sectional area of N group tin oxide electrode.
Fig. 3 is the acquisition methods flow chart of another tin oxide electrode push-in stroke shown according to an exemplary embodiment,
As shown in figure 3, step 102 includes:
Step 1021, according to the discharge of zirconium oxide, the total amount of erosion of tank block is obtained.
The step can obtain tank block using preset tank block total amount of erosion algorithm according to the discharge of zirconium oxide
Total amount of erosion.
Wherein, preset tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerIndicate the total amount of erosion of tank block, ZroutIndicate the discharge of glass furnace zirconium oxide.
Step 1022, proportionality coefficient is corroded according to the tank block in each area in the total amount of erosion of tank block and N number of area,
Obtain the tank block erosion amount in each area.
The step can corrode proportionality coefficient according to the tank block in each area in the total amount of erosion of tank block and N number of area,
Using preset region tank block erosion amount algorithm, the tank block erosion amount in each area is obtained.
Wherein, preset region tank block erosion amount algorithm includes:
Wherein, ZriIndicate the tank block erosion amount in i-th of area, FiIndicate the total surface area of tank block, jiIndicate i-th of area
Tank block corrode proportionality coefficient, 1≤i≤N.
Optionally, step 103 includes:
According to the tank block erosion amount of the erosion of electrode amount in each area and each area, obtained using preset propulsion quantity algorithm
Push-in stroke of the tin oxide electrode in each area relative to the tank block in the region.
Wherein, preset propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiIndicate the push-in stroke of the tin oxide electrode in i-th of area relative to the tank block in i-th of area, SniIndicate i-th
The tin oxide electrode erosion amount in a area, ZriIndicate the tank block erosion amount in i-th of area, 1≤i≤N.
For example, Fig. 4 is a kind of schematic cross-section of glass furnace shown according to an exemplary embodiment, such as Fig. 4
It is shown, by taking the third area of glass furnace as an example, including tank block 11, tin oxide electrode 12 and bottom of pond brick 13, wherein tin oxide
Electrode 12 may include a tin oxide electrode, also may include the identical tin oxide electrode of one group of specification.In the initial state,
Tank block 11 keeps concordant with tin oxide electrode 12.After raw material are added into glass furnace, start to manufacture glass substrate, make
During making, tank block 11 can be etched with tin oxide electrode 12.It is 2 hours that adjustment interval time, which can be preset,
Both from glass furnace start-up operation, every the push-in stroke of 2 hour adjustment once oxidation tin electrodes 12.The work since glass furnace
After making 2 hours, according to the volatile quantity of the introduction volume of tin oxide, the discharge of tin oxide and tin oxide, tin oxide electrode group is obtained
Total amount of erosion Sner=Snout+Snvol-Snin.According to the discharge of zirconium oxide, the total amount of erosion Zr of tank block is obtaineder=
Zrout.Again respectively according to the N group tin oxide electrode in glass furnace total cross-sectional area D and tank block total surface area F, the 3rd
A area's erosion of electrode proportionality coefficient k3Proportionality coefficient j is corroded with the tank block in the 3rd area3, obtain third area tin oxide electrode invade
Erosion amountWith tank block erosion amountAs shown in figure 5, region A indicates the pool wall in third area
Brick erosion amount Zr3, the tin oxide electrode erosion amount Sn in region B expression third area3, tank block 11 and tin oxide electrode 12 at this time
Plane generate dislocation, to reach tank block 11 with tin oxide electrode 12 and keep concordant, need to obtain third area tin oxide electrode
The 12 push-in stroke S relative to tank block 113=Sn3-Zr3。
It is aoxidized in the furnace of glass cellar in conclusion the disclosure is obtained by the introduction volume, discharge and volatile quantity of tin oxide
The erosion amount of tin electrode is obtained the erosion amount of tank block by the discharge of zirconium oxide, and combines the erosion of tin oxide electrode
It measures with the erosion amount of tank block and obtains push-in stroke of the tin oxide electrode relative to tank block, be able to solve the pool wall of glass furnace
After brick is etched, tin oxide electrode push-in stroke leads to the problem of deviation, keeps tin oxide electrode concordant with tank block holding, improves glass
The working efficiency of glass kiln.
Fig. 6 is a kind of acquisition device block diagram of tin oxide electrode push-in stroke shown according to an exemplary embodiment, such as Fig. 6
Shown, which is applied to glass furnace, which includes tin oxide electrode and tank block, which includes:
First erosion amount obtains module 201, the second erosion amount obtains module 202 and push-in stroke obtains module 203;
First erosion amount obtains module 201, for according to the introduction volume of tin oxide in raw material, glass furnace tin oxide
Discharge, tin oxide volatile quantity obtain tin oxide electrode erosion amount.
Second erosion amount obtains module 202 and obtains the erosion amount of tank block for the discharge according to zirconium oxide.
Push-in stroke obtains module 203, for obtaining oxidation according to the erosion amount of tin oxide electrode and the erosion amount of tank block
Push-in stroke of the tin electrode relative to tank block.
When tin oxide electrode is N group tin oxide electrode, glass furnace is divided into N number of area according to N group tin oxide electrode, wherein
When N is positive integer, optionally, the first erosion amount obtains module 201, for the outflow according to the introduction volume, tin oxide of tin oxide
The erosion of electrode proportionality coefficient in each area, the tin oxide electrode for obtaining each area are invaded in amount, the volatile quantity of tin oxide and N number of area
Erosion amount.
Second erosion amount obtains module 202, for according to each area in the discharge of glass furnace zirconium oxide and N number of area
Tank block corrodes proportionality coefficient, obtains the tank block erosion amount in each area.
Push-in stroke obtains module 203, for being invaded according to the tin oxide electrode erosion amount in each area and the tank block in each area
Erosion amount obtains the push-in stroke of the tin oxide electrode in each area relative to the tank block in the region.
Fig. 7 is the acquisition device block diagram of another tin oxide electrode push-in stroke shown according to an exemplary embodiment, such as
Shown in Fig. 7, it includes: the first total amount of erosion acquisition submodule 2011 and first area erosion amount that the first erosion amount, which obtains module 201,
Acquisition submodule 2012.
First total amount of erosion acquisition submodule 2011, for according to the introduction volume of tin oxide, the discharge of tin oxide and oxygen
Change the volatile quantity of tin, obtains the total amount of erosion of tin oxide electrode group.
First area erosion amount acquisition submodule 2012, for according to tin oxide electrode group total amount of erosion and N number of area
In each area erosion of electrode proportionality coefficient, obtain the tin oxide electrode erosion amount in each area.
Fig. 8 is the acquisition device block diagram of another tin oxide electrode push-in stroke shown according to an exemplary embodiment, such as
Shown in Fig. 8, it includes: the second total amount of erosion acquisition submodule 2021 and second area erosion amount that the second erosion amount, which obtains module 202,
Acquisition submodule 2022.
Second total amount of erosion acquisition submodule 2021 obtains total erosion of tank block for the discharge according to zirconium oxide
Amount.
Second area erosion amount acquisition submodule 2022, for according to each in the total amount of erosion of tank block and N number of area
The tank block in area corrodes proportionality coefficient, obtains the tank block erosion amount in each area.
Optionally, the first total amount of erosion acquisition submodule 2011 is used for:
According to the volatile quantity of the introduction volume of tin oxide, the discharge of tin oxide and tin oxide, always invaded using preset electrode
Lose the total amount of erosion that quantity algorithm obtains tin oxide electrode group.
Wherein, preset electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerIndicate the total amount of erosion of tin oxide electrode group, SnoutIndicate the discharge of tin oxide, SnvolIndicate oxygen
Change the volatile quantity of tin, SninIndicate the introduction volume of tin oxide.
First area erosion amount acquisition submodule 2012 is used for:
According to the erosion of electrode proportionality coefficient in each area in the total amount of erosion of tin oxide electrode group and N number of area, using pre-
If area electrodes corrode quantity algorithm, obtain the tin oxide electrode erosion amount in each area.
Preset area electrodes corrode quantity algorithm
Wherein, SniIndicate the tin oxide electrode erosion amount in i-th of area, the total cross-sectional area of D table tin oxide electrode, kiIt indicates
I-th of area's erosion of electrode proportionality coefficient, 1≤i≤N.
Optionally, the second total amount of erosion acquisition submodule 2021 is used for:
The total amount of erosion of tank block is obtained using preset tank block total amount of erosion algorithm according to the discharge of zirconium oxide.
Wherein, preset tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerIndicate the total amount of erosion of tank block, ZroutIndicate the discharge of glass furnace zirconium oxide.
Second area erosion amount acquisition submodule 2022 is used for:
Proportionality coefficient is corroded according to the tank block in each area in the total amount of erosion of tank block and N number of area, utilization is preset
Region tank block erosion amount algorithm, obtains the tank block erosion amount in each area.
Wherein, preset region tank block erosion amount algorithm includes:
Wherein, ZriIndicate that the tank block erosion amount in i-th of area, F indicate the total surface area of tank block, jiIndicate i-th of area
Tank block corrode proportionality coefficient, 1≤i≤N.
Optionally, push-in stroke obtains module 203 and is used for:
According to the tank block erosion amount of the erosion of electrode amount in each area and each area, obtained using preset propulsion quantity algorithm
Push-in stroke of the tin oxide electrode in each area relative to the tank block in the region.
Wherein, preset propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiIndicate the push-in stroke of the tin oxide electrode in i-th of area relative to the tank block in i-th of area, SniIndicate i-th
The tin oxide electrode erosion amount in a area, ZriIndicate the tank block erosion amount in i-th of area, 1≤i≤N.
About the device in above-described embodiment, wherein modules execute the concrete mode of operation in related this method
Embodiment in be described in detail, no detailed explanation will be given here.
It is aoxidized in the furnace of glass cellar in conclusion the disclosure is obtained by the introduction volume, discharge and volatile quantity of tin oxide
The erosion amount of tin electrode is obtained the erosion amount of tank block by the discharge of zirconium oxide, and combines the erosion of tin oxide electrode
It measures with the erosion amount of tank block and obtains push-in stroke of the tin oxide electrode relative to tank block, be able to solve the pool wall of glass furnace
After brick is etched, tin oxide electrode push-in stroke leads to the problem of deviation, keeps tin oxide electrode concordant with tank block holding, improves glass
The working efficiency of glass kiln.
The preferred embodiment of the disclosure is described in detail in conjunction with attached drawing above, still, the disclosure is not limited to above-mentioned reality
The detail in mode is applied, in the range of the technology design of the disclosure, those skilled in the art are considering specification and practice
After the disclosure, it is readily apparent that other embodiments of the disclosure, belongs to the protection scope of the disclosure.
It is further to note that specific technical features described in the above specific embodiments, in not lance
In the case where shield, it can be combined in any appropriate way.Simultaneously between a variety of different embodiments of the disclosure
Any combination can also be carried out, as long as it, without prejudice to the thought of the disclosure, equally should be considered as disclosure disclosure of that.
The disclosure is not limited to the precision architecture being described above out, and the scope of the present disclosure is only limited by the attached claims
System.