The acquisition methods and device of tin oxide electrode push-in stroke
Technical field
This disclosure relates to glass manufacturing area, more particularly to a kind of acquisition methods and device of tin oxide electrode push-in stroke.
Background technology
When manufacturing glass substrate using glass furnace, heat to melt raw material by electrode, and in raw material
Tin oxide can cause to corrode to the part that tin oxide electrode is exposed in kiln, it is therefore desirable to promote tin oxide electrode to make glass furnace
Stove being capable of normal work.However, the tank block of glass furnace can be also etched during glass substrate is manufactured so that promote
Tin oxide electrode afterwards protrudes tank block.
The content of the invention
The disclosure provides a kind of acquisition methods and device of tin oxide electrode push-in stroke, the pool wall to solve glass furnace
After brick is etched, the problem of tin oxide electrode push-in stroke produces deviation.
To achieve these goals, according to the first aspect of the embodiment of the present disclosure, there is provided a kind of tin oxide electrode push-in stroke
Acquisition methods, applied to glass furnace, it is characterised in that the glass furnace include tin oxide electrode and tank block, it is 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 tin oxide electrode and the erosion amount of the tank block, the tin oxide electrode is obtained relative
In the push-in stroke of the tank block.
Optionally, the tin oxide electrode is N group tin oxide electrodes, and the glass furnace is according to N groups 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, including:
According to the introduction volume of the tin oxide, the discharge of the tin oxide, the volatile quantity of the tin oxide and the N
The erosion of electrode proportionality coefficient in each area in individual 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, including:
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;
The erosion amount and the erosion amount of the tank block according to the tin oxide electrode, obtains the tin oxide electrode
Relative to the push-in stroke of the tank block, including:
According to the tin oxide electrode erosion amount in each area and the tank block erosion amount in each area, obtain described every
Push-in stroke of the tin oxide electrode in individual area relative to the tank block in the region.
Optionally, the volatilization of the introduction volume, the discharge of the tin oxide, 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, bag
Include:
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, including:
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, obtained
Take the tank block erosion amount in each area.
Optionally, the introduction volume, the discharge of the tin oxide and the tin oxide according to the tin oxide is waved
Hair amount, obtains the total amount of erosion of the tin oxide electrode group, including:
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 default electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerRepresent the total amount of erosion of the tin oxide electrode group, SnoutThe discharge of the tin oxide is represented,
SnvolRepresent the volatile quantity of the tin oxide, SninRepresent the introduction volume of the tin oxide;
The erosion of electrode ratio in each area in the total amount of erosion according to the tin oxide electrode group, and N number of area
Example coefficient, obtains the tin oxide electrode erosion amount in each area, including:
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, quantity algorithm is corroded using default area electrodes, obtains the tin oxide electrode erosion amount in each area;
The default area electrodes, which corrode quantity algorithm, to be included:
Wherein, SniThe tin oxide electrode erosion amount in i-th of area is represented, D represents the total cross-sectional area of tin oxide electrode, kiTable
Show that i-th of region electrode corrodes proportionality coefficient, 1≤i≤N.
Optionally, the discharge according to the zirconium oxide, obtaining the total amount of erosion of the tank block includes:
According to the discharge of the zirconium oxide, using default tank block total amount of erosion algorithm, the tank block is obtained
Total amount of erosion;
Wherein, the default tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerRepresent the total amount of erosion of the tank block, ZroutRepresent the discharge of the glass furnace zirconium oxide;
The tank block in each area corrodes ratio system in the total amount of erosion according to the tank block, and N number of area
Number, obtains the tank block erosion amount in each area, including:
Proportionality coefficient, profit 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 default region tank block erosion amount algorithm, the tank block erosion amount in each area is obtained;
Wherein, the default region tank block erosion amount algorithm includes:
Wherein, ZriThe tank block erosion amount in i-th of area is represented, F represents the total surface area of tank block, jiRepresent described i-th
The tank block in individual area corrodes proportionality coefficient, 1≤i≤N.
Optionally, it is 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 the tin oxide electrode relative to the tank block in the region in each area, including:
According to the erosion of electrode amount in each area and the tank block erosion amount in each area, default push-in stroke is utilized
Algorithm obtains the push-in stroke of the tin oxide electrode relative to the tank block in the region in each area;
Wherein, the default propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiRepresent the push-in stroke of the tank block of the tin oxide electrode relative to i-th of area in i-th of area, SniTable
Show the tin oxide electrode erosion amount in i-th of area, ZriRepresent the tank block erosion amount in i-th of area, 1≤i≤N.
According to the second aspect of the embodiment of the present disclosure there is provided a kind of acquisition device of tin oxide electrode push-in stroke, it is applied to
Glass furnace, it is characterised in that the glass furnace includes tin oxide electrode and tank block, described device includes:First corrodes
Measure acquisition module, the second erosion amount acquisition module and push-in stroke acquisition module;
The first erosion amount acquisition module, for according to the introduction volume of tin oxide, the glass furnace oxygen in raw material
Change the discharge of tin, the volatile quantity of tin oxide and obtain the erosion amount of the tin oxide electrode;
The second erosion amount acquisition module, for the discharge according to the zirconium oxide, obtains invading for the tank block
Erosion amount;
The push-in stroke acquisition module, the erosion for the erosion amount according to the tin oxide electrode and the tank block
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 electrodes, and the glass furnace is according to N groups tin oxide electricity
Pole is divided into N number of area, and wherein N is positive integer;
The first erosion amount acquisition module, for the introduction volume according to 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;
The second erosion amount acquisition module, for the discharge according to the glass furnace zirconium oxide 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 acquisition module, for the tin oxide electrode erosion amount according to each area and each area
Tank block erosion amount, obtains the push-in stroke of the tin oxide electrode relative to the tank block in the region in each area.
Optionally, the first erosion amount acquisition module includes:First total amount of erosion acquisition submodule and first area are invaded
Erosion amount acquisition submodule;
The first total amount of erosion acquisition submodule, for the introduction volume according to the tin oxide, the stream of 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, the second erosion amount acquisition module includes:Second total amount of erosion acquisition submodule and second area are invaded
Erosion amount acquisition submodule;
The second total amount of erosion acquisition submodule, for the discharge according to the zirconium oxide, obtains the tank block
Total amount of erosion;
The second area erosion amount acquisition submodule, for the total amount of erosion according to the tank block, and it is 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 default electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerRepresent the total amount of erosion of the tin oxide electrode group, SnoutThe discharge of the tin oxide is represented,
SnvolRepresent the volatile quantity of the tin oxide, SninRepresent 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, quantity algorithm is corroded using default area electrodes, obtains the tin oxide electrode erosion amount in each area;
The default area electrodes, which corrode quantity algorithm, to be included:
Wherein, SniThe tin oxide electrode erosion amount in i-th of area is represented, D represents the total cross-sectional area of tin oxide electrode, kiTable
Show that i-th of region electrode corrodes proportionality coefficient, 1≤i≤N.
Optionally, the second total amount of erosion acquisition submodule is used for:
According to the discharge of the zirconium oxide, using default tank block total amount of erosion algorithm, the tank block is obtained
Total amount of erosion;
Wherein, the default tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerRepresent the total amount of erosion of the tank block, ZroutRepresent the discharge of the glass furnace zirconium oxide;
The second area erosion amount acquisition submodule is used for:
Proportionality coefficient, profit 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 default region tank block erosion amount algorithm, the tank block erosion amount in each area is obtained;
Wherein, the default region tank block erosion amount algorithm includes:
Wherein, ZriThe tank block erosion amount in i-th of area is represented, F represents the total surface area of tank block, jiRepresent described i-th
The tank block in individual area corrodes proportionality coefficient, 1≤i≤N.
Optionally, the push-in stroke acquisition module is used for:
According to the erosion of electrode amount in each area and the tank block erosion amount in each area, default push-in stroke is utilized
Algorithm obtains the push-in stroke of the tin oxide electrode relative to the tank block in the region in each area;
Wherein, the default propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiRepresent the push-in stroke of the tank block of the tin oxide electrode relative to i-th of area in i-th of area, SniTable
Show the tin oxide electrode erosion amount in i-th of area, ZriRepresent the tank block erosion amount in i-th of area, 1≤i≤N.
By above-mentioned technical proposal, the disclosure obtains glass cellar for storing things by the introduction volume, discharge and volatile quantity of tin oxide
The erosion amount of tin oxide electrode in stove, the erosion amount of tank block is obtained by the discharge of zirconium oxide, and combine tin oxide electricity
The erosion amount of pole and the erosion amount of tank block obtain push-in stroke of the tin oxide electrode relative to tank block, can solve the problem that glass furnace
After the tank block of stove is etched, the problem of tin oxide electrode push-in stroke produces deviation makes tin oxide electrode keep flat with tank block
Together, the operating efficiency of glass furnace is improved.
It should be appreciated that the general description of the above and detailed description hereinafter are only exemplary and explanatory, not
The disclosure can be limited.
Brief description of the drawings
Accompanying drawing is, for providing further understanding of the disclosure, and to constitute a part for specification, with following tool
Body embodiment is used to explain the disclosure together, but does not constitute limitation of this disclosure.In the accompanying drawings:
Fig. 1 is a kind of acquisition methods flow chart of tin oxide electrode push-in stroke according to an exemplary embodiment;
Fig. 2 is the acquisition methods flow chart of another tin oxide electrode push-in stroke according to an exemplary embodiment;
Fig. 3 is the acquisition methods flow chart of another tin oxide electrode push-in stroke according to an exemplary embodiment;
Fig. 4 is a kind of schematic cross-section of glass furnace according to an exemplary embodiment;
Fig. 5 is the schematic cross-section after glass furnace is etched shown in Fig. 4;
Fig. 6 is a kind of acquisition device block diagram of tin oxide electrode push-in stroke according to an exemplary embodiment;
Fig. 7 is the acquisition device block diagram of another tin oxide electrode push-in stroke according to an exemplary embodiment;
Fig. 8 is the acquisition device block diagram of another tin oxide electrode push-in stroke according to an exemplary embodiment.
Embodiment
Here exemplary embodiment will be illustrated in detail, its example is illustrated in the accompanying drawings.Following description is related to
During accompanying drawing, unless otherwise indicated, the same numbers in different accompanying drawings represent same or analogous key element.Following exemplary embodiment
Described in embodiment do not represent all embodiments consistent with the disclosure.On the contrary, they be only with it is such as appended
The example of the consistent apparatus and method of some aspects be described in detail in claims, the disclosure.
It is each to the disclosure first before the acquisition methods of tin oxide electrode push-in stroke of disclosure offer and device are provided
Application scenarios involved by individual 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 multigroup tin oxide electrode.
Fig. 1 is a kind of acquisition methods flow chart of tin oxide electrode push-in stroke according to an exemplary embodiment, such as
Shown in Fig. 1, this method is applied to glass furnace, and the glass furnace includes tin oxide electrode and tank block, including:
Step 101, waved according to the introduction volume of tin oxide in raw material, the discharge of glass furnace tin oxide, tin oxide
Hair amount obtains the erosion amount of tin oxide electrode.
It should be noted that in the raw material of glass furnace fusing, including tin oxide, it 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 by measuring the content of tin oxide in the glass substrate that glass furnace is made.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 is obtained.
Step 102, according to the discharge of zirconium oxide, the erosion amount of tank block is obtained.
Example, in the manufacturing process of glass substrate, tank block can be also etched so that the glass that glass furnace is produced
Zirconium oxide is included in glass substrate, therefore can be obtained by measuring the content of zirconium oxide in the glass substrate that glass furnace is made
The erosion amount of tank block.
Step 103, according to the erosion amount of tin oxide electrode and the erosion amount of 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 becomes possible to obtain push-in stroke of the tin oxide electrode relative to tank block, tin oxide electrode is adjusted in glass furnace with the push-in stroke
Position in stove, 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 electrodes, glass in tin oxide electrode
Glass kiln is divided into N number of area according to N group tin oxide electrodes, and this is due to the tin oxide electrode and pool wall of glass furnace different zones
The erosion amount of brick may be different, therefore according to the position where each group electrode glass furnace can be divided into multiple regions,
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:Ratio is corroded 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:According to the tin oxide electrode erosion amount in each area and the tank block erosion amount in each area, obtain every
Push-in stroke of the tin oxide electrode in individual area relative to the tank block in the region.
It should be noted that contact area of the N group tin oxide electrodes in glass furnace can be with 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 electrodes, it is N number of
Area corresponds to the tank block in N number of area respectively.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 obtain with this push-in stroke of the tin oxide electrode relative to the tank block in the region in each area.With N number of area
Corresponding position of N number of tin oxide electrode in glass furnace of corresponding push-in stroke adjustment, 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 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, default electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerRepresent the total amount of erosion of tin oxide electrode group, SnoutRepresent the discharge of tin oxide, SnvolRepresent oxygen
Change the volatile quantity of tin, SninRepresent 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, quantity algorithm is corroded using default area electrodes, obtains the tin oxide electrode erosion amount in each area.
Default area electrodes, which corrode quantity algorithm, to be included:
Wherein, SniThe tin oxide electrode erosion amount in i-th of area is represented, D represents the total cross-sectional area of tin oxide electrode, kiTable
Show that i-th of region electrode corrodes 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 electrodes.
Fig. 3 is the acquisition methods flow chart of another tin oxide electrode push-in stroke 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 utilize default tank block total amount of erosion algorithm according to the discharge of zirconium oxide, obtain tank block
Total amount of erosion.
Wherein, default tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerRepresent the total amount of erosion of tank block, ZroutRepresent 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 the tank block in each area corrodes proportionality coefficient according to the total amount of erosion of tank block, and in N number of area,
Using default region tank block erosion amount algorithm, the tank block erosion amount in each area is obtained.
Wherein, default region tank block erosion amount algorithm includes:
Wherein, ZriRepresent the tank block erosion amount in i-th of area, FiRepresent the total surface area of tank block, jiRepresent i-th of area
Tank block corrode proportionality coefficient, 1≤i≤N.
Optionally, step 103 includes:
According to the erosion of electrode amount in each area and the tank block erosion amount in each area, obtained using default propulsion quantity algorithm
The push-in stroke of the tin oxide electrode relative to the tank block in the region in each area.
Wherein, default propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiRepresent the push-in stroke of the tank block of the tin oxide electrode relative to i-th of area in i-th of area, SniRepresent i-th
The tin oxide electrode erosion amount in individual area, ZriRepresent 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 according to an exemplary embodiment, such as Fig. 4
It is shown, by taking the 3rd 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 can also include one group of specification identical tin oxide electrode comprising a tin oxide electrode.In an initial condition,
Tank block 11 keeps concordant with tin oxide electrode 12.Added into glass furnace after raw material, start to manufacture glass substrate, in system
During making, tank block 11 can be etched with tin oxide electrode 12.It is 2 hours that adjustment interval time, which can be pre-set,
Both from glass furnace start-up operation, every the push-in stroke of 2 hours 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.The total cross-sectional area D of N group tin oxide electrodes again respectively in glass furnace and the total surface area F of tank block, the 3rd
Individual region electrode corrodes proportionality coefficient k3Proportionality coefficient j is corroded with the tank block in the 3rd area3, obtain the 3rd area tin oxide electrode invade
Erosion amountWith tank block erosion amountAs shown in figure 5, region A represents the pool wall in the 3rd area
Brick erosion amount Zr3, region B represents the tin oxide electrode erosion amount Sn in the 3rd area3, now tank block 11 and tin oxide electrode 12
Plane produce dislocation, to reach that tank block 11 keeps concordant, it is necessary to obtain the 3rd area's tin oxide electrode with tin oxide electrode 12
12 relative to tank block 11 push-in stroke S3=Sn3-Zr3。
In summary, the disclosure is obtained by the introduction volume, discharge and volatile quantity of tin oxide aoxidizes in the stove of glass cellar for storing things
The erosion amount of tin electrode, the erosion amount of tank block is obtained by the discharge of zirconium oxide, and combine the erosion of tin oxide electrode
Amount obtains push-in stroke of the tin oxide electrode relative to tank block with the erosion amount of tank block, can solve the problem that the pool wall of glass furnace
After brick is etched, the problem of tin oxide electrode push-in stroke produces deviation makes tin oxide electrode concordant with tank block holding, improves glass
The operating efficiency of glass kiln.
Fig. 6 is a kind of acquisition device block diagram of tin oxide electrode push-in stroke according to an exemplary embodiment, such as Fig. 6
Shown, the device 200 is applied to glass furnace, and the glass furnace includes tin oxide electrode and tank block, and the device 200 includes:
First erosion amount acquisition module 201, the second erosion amount acquisition module 202 and push-in stroke acquisition module 203;
First erosion amount acquisition module 201, for according to the introduction volume of tin oxide in raw material, glass furnace tin oxide
Discharge, the volatile quantity of tin oxide obtain the erosion amount of tin oxide electrode.
Second erosion amount acquisition module 202, for the discharge according to zirconium oxide, obtains the erosion amount of tank block.
Push-in stroke acquisition module 203, for the erosion amount and the erosion amount of tank block according to tin oxide electrode, obtains oxidation
Push-in stroke of the tin electrode relative to tank block.
When tin oxide electrode is N group tin oxide electrodes, glass furnace is divided into N number of area according to N group tin oxide electrodes, wherein
When N is positive integer, optionally, the first erosion amount acquisition module 201, for the introduction volume according to tin oxide, the outflow of tin oxide
The erosion of electrode proportionality coefficient in each area in amount, the volatile quantity of tin oxide and N number of area, the tin oxide electrode for obtaining each area is invaded
Erosion amount.
Second erosion amount acquisition module 202, for each area in the discharge according to 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 acquisition module 203, is invaded for the tin oxide electrode erosion amount and the tank block in each area according to each area
Erosion amount, obtains the push-in stroke of the tin oxide electrode relative to the tank block in the region in each area.
Fig. 7 is the acquisition device block diagram of another tin oxide electrode push-in stroke according to an exemplary embodiment, such as
Shown in Fig. 7, the first erosion amount acquisition module 201 includes:First total amount of erosion acquisition submodule 2011 and first area erosion amount
Acquisition submodule 2012.
First total amount of erosion acquisition submodule 2011, for introduction volume, the discharge of tin oxide and the oxygen according to tin oxide
Change the volatile quantity of tin, obtain the total amount of erosion of tin oxide electrode group.
First area erosion amount acquisition submodule 2012, for the total amount of erosion according to tin oxide electrode group, 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 according to an exemplary embodiment, such as
Shown in Fig. 8, the second erosion amount acquisition module 202 includes:Second total amount of erosion acquisition submodule 2021 and second area erosion amount
Acquisition submodule 2022.
Second total amount of erosion acquisition submodule 2021, for the discharge according to zirconium oxide, obtains total erosion of tank block
Amount.
Second area erosion amount acquisition submodule 2022, for each in the total amount of erosion according to 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 default electrode
Lose the total amount of erosion that quantity algorithm obtains tin oxide electrode group.
Wherein, default electrode total amount of erosion algorithm includes:
Sner=Snout+Snvol-Snin
Wherein, SnerRepresent the total amount of erosion of tin oxide electrode group, SnoutRepresent the discharge of tin oxide, SnvolRepresent oxygen
Change the volatile quantity of tin, SninRepresent 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.
Default area electrodes, which corrode quantity algorithm, to be included:
Wherein, SniRepresent the tin oxide electrode erosion amount in i-th of area, the total cross-sectional area of D table tin oxide electrodes, kiRepresent
I-th of region electrode corrodes proportionality coefficient, 1≤i≤N.
Optionally, the second total amount of erosion acquisition submodule 2021 is used for:
According to the discharge of zirconium oxide, using default tank block total amount of erosion algorithm, the total amount of erosion of tank block is obtained.
Wherein, default tank block total amount of erosion algorithm includes:
Zrer=Zrout
Wherein, ZrerRepresent the total amount of erosion of tank block, ZroutRepresent 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, using default
Region tank block erosion amount algorithm, obtains the tank block erosion amount in each area.
Wherein, default region tank block erosion amount algorithm includes:
Wherein, ZriThe tank block erosion amount in i-th of area is represented, F represents the total surface area of tank block, jiRepresent i-th of area
Tank block corrode proportionality coefficient, 1≤i≤N.
Optionally, push-in stroke acquisition module 203 is used for:
According to the erosion of electrode amount in each area and the tank block erosion amount in each area, obtained using default propulsion quantity algorithm
The push-in stroke of the tin oxide electrode relative to the tank block in the region in each area.
Wherein, default propulsion quantity algorithm includes:
Si=Sni-Zri
Wherein, SiRepresent the push-in stroke of the tank block of the tin oxide electrode relative to i-th of area in i-th of area, SniRepresent i-th
The tin oxide electrode erosion amount in individual area, ZriRepresent the tank block erosion amount in i-th of area, 1≤i≤N.
On the device in above-described embodiment, wherein modules perform the concrete mode of operation in relevant this method
Embodiment in be described in detail, explanation will be not set forth in detail herein.
In summary, the disclosure is obtained by the introduction volume, discharge and volatile quantity of tin oxide aoxidizes in the stove of glass cellar for storing things
The erosion amount of tin electrode, the erosion amount of tank block is obtained by the discharge of zirconium oxide, and combine the erosion of tin oxide electrode
Amount obtains push-in stroke of the tin oxide electrode relative to tank block with the erosion amount of tank block, can solve the problem that the pool wall of glass furnace
After brick is etched, the problem of tin oxide electrode push-in stroke produces deviation makes tin oxide electrode concordant with tank block holding, improves glass
The operating efficiency of glass kiln.
The preferred embodiment of the disclosure is described in detail above in association with accompanying drawing, 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, other embodiments of the disclosure are readily apparent that, the protection domain of the disclosure is belonged to.
It is further to note that each particular technique feature described in above-mentioned embodiment, in not lance
In the case of shield, it can be combined by any suitable means.Simultaneously between a variety of embodiments of the disclosure
It can also be combined, as long as it is without prejudice to the thought of the disclosure, it should equally 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 appended claim
System.