CN212595532U - Automatic proportion glaze slip agitator adjusts - Google Patents

Abstract

An automatic proportion-adjusting glaze slurry stirring cylinder comprises a proportion meter; the specific gravity measuring meter comprises a measuring pipe, the measuring pipe comprises an upper measuring pipe and a lower measuring pipe, a spring is arranged in the upper measuring pipe, the upper part of the spring is connected with the top of the inner pipe wall of the upper measuring pipe, an instrument needle is arranged in the middle of the spring, a hanging rope is arranged in the lower measuring pipe, one end of the hanging rope is connected with the lower part of the spring, and a gravity ball is hung at the other end of the hanging rope; the upper measuring tube is provided with a conductive strip, and the back surface of the instrument needle is in mutual contact with the surface of the conductive strip; the conducting strip is including setting up in go up inside left side conducting strip and the right side conducting strip of survey tube, the right side conducting strip including set up in go up the first right side conducting strip on survey tube upper portion with set up in go up the second right side conducting strip of survey tube lower part. The utility model provides an automatic transfer proportion glaze slip agitator realizes accurate ground automatic measure glaze slip proportion, reduces artifical measuring step, improves production efficiency.

Description

Automatic proportion glaze slip agitator adjusts

Technical Field

The utility model relates to a glaze slip stirring technical field especially relates to an automatic transfer proportion glaze slip agitator.

Background

The production process of the ceramic glazed tile needs to use glaze slip, and the specific gravity of the glaze slip is not too low in the storage process, otherwise, the glaze slip is easy to precipitate. In order to ensure easy storage of the glaze slip in the glaze slip processing workshop, a higher specific gravity is generally adjusted in the glaze slip processing process. When the glaze slip is transferred to a forming workshop for production and use, water is added into a glaze slip stirring cylinder to adjust the production and use specific gravity meeting the production process requirements. Usually, the specific gravity adjusting process is to repeatedly adjust and measure the specific gravity of the glaze slip by using a specific gravity cup and an electronic scale for many times through a glaze line worker, and finally the specific gravity of the glaze slip required by the process is realized. The manual specific gravity measuring process has complicated steps and time consumption, has high requirements on the proficiency of operators and the workshop environment, and has low measuring efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an automatic proportion glaze slip agitator of transferring to the defect in the background art, realize accurate ground automatic measure glaze slip proportion, reduce manual measurement's step, improve production efficiency.

To achieve the purpose, the utility model adopts the following technical proposal:

an automatic proportion-adjusting glaze slurry stirring cylinder comprises a proportion meter;

the specific gravity measuring meter comprises a measuring pipe, the measuring pipe comprises an upper measuring pipe and a lower measuring pipe, a spring is arranged in the upper measuring pipe, the upper part of the spring is connected with the top of the inner pipe wall of the upper measuring pipe, an instrument needle is arranged in the middle of the spring, a hanging rope is arranged in the lower measuring pipe, one end of the hanging rope is connected with the lower part of the spring, and a gravity ball is hung at the other end of the hanging rope;

the upper measuring tube is provided with a conductive strip, and the back surface of the instrument needle is in mutual contact with the surface of the conductive strip;

the conducting strip is including setting up in go up inside left side conducting strip and the right side conducting strip of survey tube, the right side conducting strip including set up in go up the first right side conducting strip on survey tube upper portion with set up in go up the second right side conducting strip of survey tube lower part.

Preferably, a separation is provided between the first right conductive strip and the second right conductive strip.

Preferably, the device also comprises a low-specific gravity slurry stirring cylinder, a first alternating current power supply and a first timer;

the low specific gravity slurry stirring cylinder is provided with a first glaze slurry conveying pump, the output end of the first glaze slurry conveying pump is connected with the input end of the first alternating current power supply through a wire, the output end of the first alternating current power supply is connected with the input end of the first timer through a wire, and the input end of the first timer is connected with the input end of the right conductive bar.

Preferably, the device also comprises a high specific gravity slurry stirring cylinder, a second timer and a second alternating current power supply;

the high specific gravity slurry stirring cylinder is provided with a second glaze slurry conveying pump, the output end of the second glaze slurry conveying pump is connected with the input end of the second timer through a wire, and the output end of the second timer is connected with the input end of the left conductive bar; the output end of the second glaze slip delivery pump is connected with the input end of the second alternating current power supply through a wire, and the output end of the second alternating current power supply is connected with the instrument needle.

Preferably, an instrument panel is arranged on the outer pipe wall of the upper measuring pipe;

the pipe wall of the lower measuring pipe is provided with a plurality of through holes;

the bottom of the lower measuring pipe is provided with a liquid inlet.

Preferably, a partition plate is arranged between the upper measuring tube and the lower measuring tube, an opening is formed in the center of the partition plate, and the hanging rope penetrates through the opening to be connected with the lower portion of the spring.

Preferably, the method also comprises a glaze slip production stirring cylinder;

the outer wall of the measuring tube is provided with a glaze cylinder wall hook;

the specific gravity meter is hung on the inner wall of the glaze slurry production stirring cylinder through the glaze cylinder wall hook, the upper measuring pipe is higher than the top of the glaze slurry production stirring cylinder, and the lower measuring pipe is positioned in the glaze slurry production stirring cylinder.

Preferably, the left side of the instrument panel is provided with elasticity value scales, and the right side of the instrument panel is provided with specific gravity value scales.

Preferably, the low specific gravity slurry stirring cylinder and the high specific gravity slurry stirring cylinder are both provided with glaze conveying pipes.

Preferably, the instrument needle is made of a conductive material.

Has the advantages that:

the utility model discloses an utilize the spring, hang rope, gravity ball and instrument needle measurement the elasticity of gravity ball in the glaze slurry, the conversion obtains specific gravity value to measure specific gravity value, simultaneously through setting up the busbar and being connected with instrument needle point in last survey intraductal, utilize timer and alternating current power supply, the break-make electricity of control high proportion thick liquids agitator and low proportion thick liquids agitator realizes accurate ground automatic measure glaze slurry proportion, reduces artifical measuring step, improves production efficiency.

Drawings

FIG. 1 is a schematic structural view of an automatic specific gravity adjusting glaze slurry mixing tank of the present invention;

FIG. 2 is a side view of the specific gravity meter according to the present invention;

FIG. 3 is an internal side view of the specific gravity gauge of the present invention;

FIG. 4 is a schematic structural diagram of a mixing tank and a specific gravity meter for producing glaze slurry according to the present invention.

Wherein: the device comprises a production glaze slurry stirring cylinder 1, a glaze slurry stirring pump 11, a low specific gravity slurry stirring cylinder 2, a first timer 21, a first alternating current power supply 22, a first glaze slurry conveying pump 23, a first glaze conveying pipe 24, a high specific gravity slurry stirring cylinder 3, a second timer 31, a second alternating current power supply 32, a second glaze slurry conveying pump 33, a second glaze conveying pipe 34, a specific gravity meter 4, an upper measuring pipe 41, a left conducting bar 411, a first right conducting bar 412, a second right conducting bar 413, a lower measuring pipe 42, a through hole 421, a spring 43, an instrument needle 44, a hanging rope 45, a gravity ball 46, a partition plate 47, an opening 471, a glaze cylinder wall hook 48 and an instrument panel 49.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The utility model relates to an automatic proportion-adjusting glaze slip mixing tank, as shown in figures 2 and 3, comprising a proportion meter 4;

the specific gravity measuring meter 4 comprises a measuring pipe, the measuring pipe comprises an upper measuring pipe 41 and a lower measuring pipe 42, a spring 43 is arranged inside the upper measuring pipe 41, the upper part of the spring 43 is connected with the top of the inner pipe wall of the upper measuring pipe 41, an instrument needle 44 is arranged in the middle of the spring 43, a hanging rope 45 is arranged inside the lower measuring pipe 42, one end of the hanging rope 45 is connected with the lower part of the spring 43, and a gravity ball 46 is hung at the other end;

the upper measuring tube 41 is provided with a conductive strip, and the back surface of the instrument needle 44 is in contact with the surface of the conductive strip;

the conductive strips include a left conductive strip 411 and a right conductive strip disposed inside the upper tube 41, and the right conductive strips include a first right conductive strip 412 disposed on the upper portion of the upper tube 41 and a second right conductive strip 413 disposed on the lower portion of the upper tube 41.

In order to ensure easy storage of the glaze slip in the glaze slip processing workshop, a higher specific gravity is generally adjusted in the glaze slip processing process. When the glaze slip is transferred to a forming workshop for production and use, water is added into a glaze slip stirring cylinder to adjust the production and use specific gravity meeting the production process requirements. Usually, the specific gravity adjusting process is to repeatedly adjust and measure the specific gravity of the glaze slip by using a specific gravity cup and an electronic scale for many times through a glaze line worker, and finally the specific gravity of the glaze slip required by the process is realized. The manual specific gravity measuring process has complicated steps and time consumption, has high requirements on the proficiency of operators and the workshop environment, and has low measuring efficiency.

In order to solve the above problems, the application designs an automatic proportion glaze slip agitator of transferring, including proportion meter 4, proportion meter 4 is including surveying buret, survey the pipe wall of buret transparent, conveniently observe scale data and the inside condition of body, survey buret and include upper portion and lower part, upper portion is for surveying pipe 41, and the lower part is for surveying pipe 42 down, it is provided with spring 43 to go up to survey the inside of pipe 41, and spring 43 upper portion is fixed with the inner wall at last survey pipe 41 top, makes things convenient for the firm measurement of spring 43, and spring 43 middle part is provided with instrument needle 44, instrument needle 44 is used for cooperating the scale to look over the specific gravity size of measuring; the lower measuring tube 42 is internally provided with a hanging rope 45, one end of the hanging rope 45 is connected with the lower part of the spring 43, the other end of the hanging rope 45 is provided with a gravity ball 46, and the specific gravity value is obtained by means of the ratio of the buoyancy and the elasticity of the gravity ball 46 in the glaze slurry.

Meanwhile, a left conducting strip 411 is arranged on the left side in the upper measuring tube 41, a first right conducting strip 412 is arranged on the upper portion of the right side, a second right conducting strip 413 is arranged on the lower portion of the right side, and the meter needle 44 and the conducting strips are electrified to control the power-on and power-off of the low-specific gravity glaze slurry mixing tank and the high-specific gravity glaze slurry mixing tank, so that the specific gravity of the glaze slurry is controlled to reach a target value.

Preferably, a separation is disposed between the first right conductive strip 412 and the second right conductive strip 413.

Preferably, the low specific gravity slurry stirring cylinder 2 and the high specific gravity slurry stirring cylinder 3 are both provided with glaze conveying pipes.

Preferably, the meter needle 44 is made of a conductive material.

Preferably, as shown in fig. 4, the apparatus further comprises a low specific gravity slurry stirring cylinder 2, a first alternating current power source 22 and a first timer 21;

the low specific gravity slurry stirring cylinder 2 is provided with a first glaze slurry conveying pump 23, an output end of the first glaze slurry conveying pump 23 is connected with an input end of a first alternating current power supply 22 through a wire, an output end of the first alternating current power supply 22 is connected with an input end of a first timer 21 through a wire, and an input end of the first timer 21 is connected with an input end of the right conductive bar.

Preferably, as shown in fig. 4, the apparatus further comprises a high specific gravity slurry stirring cylinder 3, a second timer 31 and a second alternating current power supply 32;

the high specific gravity slurry stirring cylinder 3 is provided with a second glaze slurry conveying pump 33, the output end of the second glaze slurry conveying pump 33 is connected with the input end of the second timer 31 through a wire, and the output end of the second timer 31 is connected with the input end of the left conductive bar 411; the output end of the second glaze slurry delivery pump 33 is connected with the input end of the second alternating current power supply 32 through a wire, and the output end of the second alternating current power supply 32 is connected with the instrument needle 44.

The slurry stored in the low specific gravity slurry stirring cylinder 2 generally refers to water in production application, and the slurry stored in the high specific gravity slurry stirring cylinder 3 generally refers to glaze raw slurry in production application; by suspending the specific gravity meter 4 on the inner wall of the glaze slurry production stirring cylinder 1, the first right conductive strip 412 and the second right conductive strip 413 are cut off at the position of the specific gravity target value to be adjusted by adjusting the positions of the first right conductive strip 412 and the second right conductive strip 413, and the back surface of the meter hand 44 and the surfaces of the conductive strips are in contact with each other. Setting a reasonable time value for the first timer 21 and the second timer 31, setting two time settings on the first timer 21 and the second timer 31, setting the first time as an on-state time and the second time as an off-state time, starting the timer after the first timer 21 and the second timer 31 are powered on, executing the on-state and the off-state circularly, and ending the circulation when the first timer 21 and the second timer 31 are powered off, wherein the timer in the application is the prior art capable of setting two time points, and the working principle of the timer is not described too much;

then, the power supplies of the glaze slurry stirring pump 11 in the production glaze slurry stirring cylinder 1, the first glaze slurry delivery pump 23 in the low specific gravity slurry stirring cylinder 2 and the second glaze slurry delivery pump 33 in the high specific gravity slurry stirring cylinder 3 are respectively electrified. At this time, no glaze slurry exists in the glaze slurry production stirring cylinder 1, the pointing scale of the instrument needle 44 is 0, which is smaller than the specific gravity target value, at this time, the instrument needle 44 is in contact with the left conductive bar 411 and the second right conductive bar 413, so that the second glaze slurry delivery pump 33, the second timer 31, the second alternating current power supply 32, the instrument needle 44, the left conductive bar 411 and the second right conductive bar 413 of the high specific gravity slurry stirring cylinder 3 form a loop, the high specific gravity slurry stirring cylinder 3 is in an energized state, the second glaze slurry delivery pump 33 of the high specific gravity slurry stirring cylinder 3 starts to work, glaze raw slurry in the high specific gravity slurry stirring cylinder 3 is pumped into the glaze slurry production stirring cylinder 1 through the second glaze delivery pipe 34, when the gravity ball 46 is covered by the glaze raw slurry, the instrument needle 44 rises due to the buoyancy of the gravity ball 46, and when the gravity ball 46 is completely covered by the glaze raw slurry, the glaze raw slurry has a specific gravity value larger than the target value, when the meter needle 44 leaves the second right conductive strip 413 and rises to be in contact with the first right conductive strip 412, the loop of the high specific gravity slurry mixing cylinder 3 is disconnected, the second glaze slurry conveying pump 33 is powered off and stops working, so that the first glaze slurry conveying pump 23, the first timer 21, the first alternating current power supply 22, the meter needle 44, the left conductive strip 411 and the first right conductive strip 412 of the low specific gravity slurry mixing cylinder 2 form a loop, the low specific gravity slurry mixing cylinder 2 is in a powered-on state, the first glaze slurry conveying pump 23 of the low specific gravity slurry mixing cylinder 2 starts working, and water in the low specific gravity slurry mixing cylinder 2 is pumped into the production glaze slurry mixing cylinder 1 through the first glaze conveying pipe 24 for specific gravity adjustment. When the specific gravity is adjusted to the target specific gravity value, the instrument needle 44 is positioned at the separation position of the first right conductive strip 412 and the second right conductive strip 413, the loop of the low specific gravity slurry stirring cylinder 2 is disconnected, and the first glaze slurry delivery pump 23 is powered off and stops working.

The glaze total amount can be controlled and adjusted by adjusting the length of the hanging rope 45 and then adjusting the position of the gravity ball 46.

In this application, the glaze precision can be transferred in the control of timer, reserves stirring homogenization time. In the process of adjusting the specific gravity of the glaze slurry production stirring cylinder 1, the second timer 31 of the high specific gravity slurry stirring cylinder 3 is mainly responsible for the hollow glazing operation, so the power-on state time can be fixed to a certain length (according to the actual glaze slurry conveying flow and the capacity of the stirring cylinder) in the second timer 31 of the high specific gravity slurry stirring cylinder 3, generally about 10 minutes is recommended, and a value can be set at will in the power-off state time. The stirring convection homogenization of the original glaze slip and water by the glaze slip stirring pump 11 needs about 10 to 15 seconds approximately, and the time of the power-on state and the power-off state can be positioned for 10 to 15 seconds in the first timer 21 of the low specific gravity slip stirring cylinder 2. The internal time switch settings of the first timer 21 of the low specific gravity slurry mixing tank 2 can be different, the shorter the time setting of the power-on state is, the less the water pumping amount is, the smaller the change of the specific gravity value of the glaze slurry in the production glaze slurry mixing tank 1 is, the longer the time setting of the power-off state is, the longer the mixing time of the glaze slurry mixing pump 11 is, and the better the glaze slurry homogenization is. The smaller the water amount is added, the longer the stirring time is, and the more accurate the specific gravity value is adjusted.

Preferably, as shown in fig. 2, an instrument panel 49 is arranged on the outer wall of the upper measuring tube 41; the left side of the instrument panel 49 is provided with elasticity value scales, and the right side is provided with specific gravity value scales.

The pipe wall of the lower measuring pipe 42 is provided with a plurality of through holes 421;

the bottom of the lower measuring pipe 42 is provided with a liquid inlet.

Elastic values and specific gravity values are respectively engraved on the left side and the right side of the instrument panel 49, and the elastic values are pointed by the instrument needles 44, so that corresponding specific gravity values are obtained. The pipe wall of lower survey pipe 42 has been seted up a plurality of through-holes 421, and has seted up the inlet in the bottom, and in this embodiment, the inlet does the bottom of lower survey pipe 42 does not seal, survey pipe 42 down is inside hollow structure, sets up through-hole 421, and is convenient survey pipe 42 down when measuring, the glaze slip can get into down inside survey pipe 42, conveniently produces the glaze slip convection current in glaze slip agitator 1 and the lower survey pipe 42.

Preferably, a partition plate 47 is arranged between the upper measuring tube 41 and the lower measuring tube 42, an opening 471 is arranged at the center of the partition plate 47, and the hanging rope 45 passes through the opening 471 to be connected with the lower part of the spring 43.

The spring 43 is arranged in the upper measuring pipe 41, and the partition plate 47 is arranged, so that the phenomenon that the glaze slurry in the lower measuring pipe 42 is fed into the upper measuring pipe 41 during stirring and is adhered to the spring 43 to influence the measuring accuracy can be effectively avoided.

Preferably, as shown in fig. 1, the method further comprises a glaze slip production stirring cylinder 1;

the outer wall of the measuring tube is provided with a glaze cylinder wall hook 48;

the specific gravity meter 4 is hung on the inner wall of the production glaze slurry stirring cylinder 1 through the glaze cylinder wall hook 48, the upper measuring pipe 41 is higher than the top of the production glaze slurry stirring cylinder 1, and the lower measuring pipe 42 is positioned in the production glaze slurry stirring cylinder 1.

During measurement, the glaze cylinder wall hook 48 can hang the specific gravity measuring meter 4 on the edge of the inner wall of the glaze slurry production stirring cylinder 1 to form a fixed point, so that accidents caused by manual holding are avoided.

This application is when using, will earlier the proportion meter 4 hang in 1 inner wall edge of production glaze slurry agitator tank, 4 upper portions of proportion meter are higher than 1 upper portion edge of production glaze slurry agitator tank avoids the glaze slurry to get into 4 upper portions of proportion meter, goes up survey pipe 41 promptly, glues even spring 43, influences measurement accuracy. Then, the glaze slurry with the specific gravity to be adjusted is injected into the production glaze slurry stirring cylinder 1, the glaze slurry stirring pump 11 is started, and the gravity ball 46 must be submerged at the height of the glaze slurry in the production glaze slurry stirring cylinder 1. The weight of the gravity ball 46 must be greater than the overall buoyancy of the gravity ball 46. When the meter hand 44 shows a specific gravity greater than the required value, the specific gravity of the glaze slip is reduced by adding water, and when the meter hand 44 shows a specific gravity less than the required value, the specific gravity of the glaze slip is raised by adding the original glaze slip.

The specific gravity meter 4 of the present application operates as follows:

when the gravity meter 4 is not set in the glaze slurry, the gravity ball 46 pulls up the spring 43 by gravity, and the meter hand 44 on the meter panel 49 indicates an elastic force F_{Bullet 1}The corresponding specific gravity value p1 is 0, the specific gravity is the ratio of the density of the liquid to the density of water, and the density of the liquid to be measured is equal to the specific gravity value in value because the density of water is 1. After the specific gravity meter 4 is placed in the glaze slip, according to an Archimedes principle buoyancy formula, the calculation result is as follows:

when the gravimeter is not put into the glaze slip: the value of the hydrometer is as follows: p1= 0; f_{Bullet 1}= G_{Ball with ball-shaped section}；

When a hydrometer is put into the glaze slip: the value of the hydrometer is as follows: p 2;

F_{bullet 2}=G_{Ball with ball-shaped section}-F_{Ball float}；

F_{Ball float}=p2gV_{Ball with ball-shaped section} ；

F_{Bullet 2}=G_{Ball with ball-shaped section}-p2gV_{Ball with ball-shaped section}；

The conversion can obtain: p2= (G)_{Ball with ball-shaped section}-F_{Bullet 2}）/gV_{Ball with ball-shaped section}=（F_{Bullet 1}-F_{Bullet 2}）/gV_{Ball with ball-shaped section}；

Wherein:

1, p 1: an initial specific gravity value;

2, p 2: measuring a specific gravity value;

3.F_{bullet 1}: the initial elasticity value displayed by the hydrometer;

4.F_{bullet 2}: the measured elasticity value displayed by the hydrometer;

5.G_{ball with ball-shaped section}: the gravity value of the gravity ball 6;

6.F_{ball float}: the buoyancy value of the gravity ball 6 in the glaze slip;

7.V_{ball with ball-shaped section}: the volume of the gravity ball 6;

8, g: a gravitational acceleration value.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (10)

1. The utility model provides an automatic proportion glaze slip agitator of transferring which characterized in that: comprises a specific gravity meter;

the specific gravity measuring meter comprises a measuring pipe, the measuring pipe comprises an upper measuring pipe and a lower measuring pipe, a spring is arranged in the upper measuring pipe, the upper part of the spring is connected with the top of the inner pipe wall of the upper measuring pipe, an instrument needle is arranged in the middle of the spring, a hanging rope is arranged in the lower measuring pipe, one end of the hanging rope is connected with the lower part of the spring, and a gravity ball is hung at the other end of the hanging rope;

the upper measuring tube is provided with a conductive strip, and the back surface of the instrument needle is in mutual contact with the surface of the conductive strip;

the conducting strip is including setting up in go up inside left side conducting strip and the right side conducting strip of survey tube, the right side conducting strip including set up in go up the first right side conducting strip on survey tube upper portion with set up in go up the second right side conducting strip of survey tube lower part.

2. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 1, wherein:

and a separation part is arranged between the first right conductive strip and the second right conductive strip.

3. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 1, wherein:

the device also comprises a low-specific gravity slurry stirring cylinder, a first alternating current power supply and a first timer;

the low specific gravity slurry stirring cylinder is provided with a first glaze slurry conveying pump, the output end of the first glaze slurry conveying pump is connected with the input end of the first alternating current power supply through a wire, the output end of the first alternating current power supply is connected with the input end of the first timer through a wire, and the input end of the first timer is connected with the input end of the right conductive bar.

4. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 3, wherein:

the high-specific gravity slurry stirring device also comprises a high-specific gravity slurry stirring cylinder, a second timer and a second alternating current power supply;

the high specific gravity slurry stirring cylinder is provided with a second glaze slurry conveying pump, the output end of the second glaze slurry conveying pump is connected with the input end of the second timer through a wire, and the output end of the second timer is connected with the input end of the left conductive bar; the output end of the second glaze slip delivery pump is connected with the input end of the second alternating current power supply through a wire, and the output end of the second alternating current power supply is connected with the instrument needle.

5. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 1, wherein:

an instrument panel is arranged on the outer pipe wall of the upper measuring pipe;

the pipe wall of the lower measuring pipe is provided with a plurality of through holes;

the bottom of the lower measuring pipe is provided with a liquid inlet.

6. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 1, wherein:

a partition plate is arranged between the upper measuring tube and the lower measuring tube, an opening is formed in the center of the partition plate, and the hanging rope penetrates through the opening to be connected with the lower portion of the spring.

7. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 1, wherein:

also comprises a glaze slip production stirring cylinder;

the outer wall of the measuring tube is provided with a glaze cylinder wall hook;

the specific gravity meter is hung on the inner wall of the glaze slurry production stirring cylinder through the glaze cylinder wall hook, the upper measuring pipe is higher than the top of the glaze slurry production stirring cylinder, and the lower measuring pipe is positioned in the glaze slurry production stirring cylinder.

8. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 3, wherein:

the left side of the instrument panel is provided with elasticity value scales, and the right side is provided with specific gravity value scales.

9. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 4, wherein:

and the low-specific gravity slurry stirring cylinder and the high-specific gravity slurry stirring cylinder are both provided with glaze conveying pipes.

10. The automatic specific gravity adjusting glaze slurry stirring cylinder as claimed in claim 1, wherein:

the instrument needle is made of a conductive material.

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