CN112552078A

CN112552078A - Color porcelain sintering device capable of adjusting temperature according to mercury divergence

Info

Publication number: CN112552078A
Application number: CN202110026296.4A
Authority: CN
Inventors: 仝瑞帆
Original assignee: Shanghai Frame Trading Co ltd
Current assignee: Chaozhou Yiguang Ceramics Industry Co ltd
Priority date: 2021-01-08
Filing date: 2021-01-08
Publication date: 2021-03-26
Anticipated expiration: 2041-01-08
Also published as: CN112552078B

Abstract

The invention discloses a colored porcelain sintering device for adjusting temperature according to mercury divergence, which comprises a machine body, wherein a receiving cavity is arranged in the machine body, a temperature control mechanism is arranged in the receiving cavity, the temperature control mechanism comprises a temperature insulation plate fixedly arranged on the inner wall of the lower side of the receiving cavity, the left end surface of the temperature insulation plate is fixedly provided with a limiting block and a plug, the plug is positioned on the upper side of the limiting block, and a first power supply block is arranged on the left end surface of the temperature insulation plate in a sliding manner. Thereby adjusting the sintering environment of the ceramic more stably.

Description

Color porcelain sintering device capable of adjusting temperature according to mercury divergence

Technical Field

The invention relates to the field of ceramic processing equipment, in particular to a colored porcelain sintering device capable of adjusting temperature according to mercury divergence.

Background

The ceramic sintering is a process of densifying a ceramic blank at high temperature, which is a step that the ceramic must be subjected to before being made into a finished product, the existing colored porcelain is often added with some mercury in glazed glaze to enable the glaze to be better combined with the ceramic blank, but when the sintering temperature is not high or the sintering time is not enough, the mercury in the glaze can remain in the ceramic, and then can seep out in the use process in the future to influence the health of a user.

Disclosure of Invention

The invention aims to provide a color porcelain sintering device capable of adjusting temperature according to mercury divergence, which overcomes the problems.

The invention is realized by the following technical scheme.

The invention relates to a color porcelain sintering device for adjusting temperature according to mercury divergence, which comprises a machine body, wherein a containing cavity is arranged in the machine body, a temperature control mechanism is arranged in the containing cavity, the temperature control mechanism comprises a temperature insulating plate fixedly arranged on the inner wall of the lower side of the containing cavity, the left end surface of the temperature insulating plate is fixedly provided with a limiting block and a plug, the plug is positioned on the upper side of the limiting block, the left end surface of the temperature insulating plate is provided with a first power supply block in a sliding manner, the first power supply block is positioned between the limiting block and the plug, a first spring is fixedly arranged between the first power supply block and the limiting block, the inner wall of the left side of the containing cavity is fixedly provided with a pneumatic machine shell, the lower end surface of the pneumatic machine shell is fixedly provided with a pneumatic machine, a pneumatic cavity is arranged in the pneumatic machine shell, the upper end surface of the pneumatic cavity is fixedly provided with a push rod, the upper end face of the top block is fixedly provided with a sliding sheet, the upper end face of the air pressure shell is fixedly provided with a sliding rheostat, the sliding rheostat is positioned on the right side of the push rod, the right end face of the sliding sheet is attached to the left end face of the sliding rheostat, the right end face of the heat insulation plate is fixedly provided with a heating block, the plug, the sliding rheostat and the sliding sheet are connected through a first wire, one end of the first wire is connected with the sliding sheet, and the other end of the first wire is connected with the sliding rheostat;

the detection mechanism is arranged in the containing cavity and comprises a detection box fixedly arranged between the heat insulation plate and the inner wall of the upper side of the containing cavity, a detection cavity is arranged in the detection box, a partition plate is fixedly arranged on the inner wall of the upper side of the detection cavity, a mercury probe is fixedly arranged on the lower end surface of the partition plate, a first motor is fixedly arranged on the inner wall of the left side of the detection cavity, a first motor is rotationally arranged on the right end surface, a first rotating shaft penetrates through the left and right end surfaces of the partition plate, the right end surface of the first rotating shaft is rotationally arranged on the inner wall of the right side of the detection cavity, a sector gear and blades are fixedly arranged on the first rotating shaft, the sector gear and the blades are respectively positioned on the left and right sides of the partition plate, a filter plate is fixedly arranged between the partition plate and the inner wall of the right side of the detection cavity, a, a fixed block is fixedly arranged on the inner wall of the left side of the detection cavity, the fixed block is positioned on the lower side of the first motor, a torsion groove is arranged in the fixed block, a torsion spring is arranged between the inner walls of the torsion groove in a rotating manner, a second rotating shaft is arranged on the inner wall of the left side of the torsion groove in a rotating manner, the second rotating shaft penetrates through the partition plate and the left and right end faces of the scraper, the inner part of the scraper is connected with the second rotating shaft through threads, a transmission gear is fixedly arranged on the second rotating shaft and positioned on the left side of the partition plate, and the sector gear can be;

accomodate the intracavity and be equipped with pressurize mechanism, pressurize mechanism is in including fixed setting accomodate the gas receiver of chamber upside inner wall, be equipped with the gas storage chamber in the gas receiver, the fixed air pump that is equipped with of gas storage chamber downside inner wall, the gas receiver with the fixed connecting plate that is equipped with between the collecting box, the fixed dog that is equipped with of gas receiver left end face, it is equipped with the connecting rod to slide on the dog, the connecting rod runs through terminal surface about the dog, terminal surface is fixed second slider and the first slider of being equipped with respectively about the connecting rod, the second slider with first slider right-hand member face all slides and sets up the gas receiver left end face, the fixed pressure sensor that is equipped with of gas receiver left end face, pressure sensor is located the second slider upside, pressure sensor in second slider snap-on is equipped with the second spring.

Preferably, temperature-control mechanism still includes accomodate the supporting seat that chamber downside inner wall slided and is equipped with, accomodate the fixed third motor that is equipped with of chamber left side inner wall, the first motor is located the aerostatic press downside, the first motor right-hand member rotates and is equipped with the third pivot, the third pivot runs through terminal surface about the thermal insulation board with the supporting seat left end face, inside threaded connection through of supporting seat the third pivot, the fixed reel that is equipped with in the third pivot, the reel is located thermal insulation board left side, the reel with first power supply piece is connected through first string.

Preferably, detection mechanism still including fixed the setting accomodate the liquid reserve tank of chamber left side inner wall, the liquid reserve tank is located the detection case downside, the liquid reserve tank with fixed plate that is equipped with between the detection case, the fixed plate with accomodate and slide between the chamber left side inner wall and be equipped with the sliding plate, the fixed third motor and the starter that is equipped with of liquid reserve tank up end, the third motor with the starter is located respectively the plug left and right sides side, the third motor up end rotates and is equipped with the fourth pivot, the fourth pivot runs through terminal surface about the sliding plate, the sliding plate is inside through threaded connection the fourth pivot, the fixed second power supply piece that is equipped with of partition temperature board left end face, the second power supply piece the starter the third motor with the mercury probe passes through the second connection of electric lines.

Preferably, be equipped with the liquid reserve tank in the liquid reserve tank, the fixed water pump that is equipped with of liquid reserve tank downside inner wall, the water pump with it passes through the water piping connection to detect chamber downside inner wall, the liquid reserve tank right-hand member face slides and is equipped with the third slider, the fixed trigger that is equipped with of liquid reserve tank right-hand member face, the trigger is located third slider downside, it is equipped with the floating block to detect the intracavity, the floating block with the third slider passes through the second string and connects.

Preferably, the elasticity of the second spring is greater than the gravity of the second sliding block, the connecting rod and the first sliding block, the floating block is a light wood block, the liquid level in the detection cavity is higher than the mercury probe, and the buoyancy of the floating block is greater than the gravity of the third sliding block.

The invention has the beneficial effects that: according to the invention, flue gas generated during sintering is introduced into the acid solution, and then the mercury probe is used for detecting the mercury content in the acid solution to reflect whether mercury is diffused or not, when mercury is not detected, the built-in push plate is used for reducing the access resistance of the slide rheostat so as to raise the heating temperature, so that mercury is diffused out, mercury is prevented from remaining in the ceramic to influence the body health of a user, and the pressure sensor is used for reacting the air pressure in the device during sintering so as to adjust, so that the ceramic sintering environment is more stable.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the embodiment of the present invention at A in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-2, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The color porcelain sintering device for adjusting temperature according to mercury divergence amount, which is described with reference to fig. 1-2, includes a machine body 10, a receiving cavity 11 is provided in the machine body 10, a temperature control mechanism 80 is provided in the receiving cavity 11, the temperature control mechanism 80 includes a temperature insulation plate 12 fixedly provided on the inner wall of the lower side of the receiving cavity 11, a limit block 25 and a plug 29 are fixedly provided on the left end surface of the temperature insulation plate 12, the plug 29 is located on the upper side of the limit block 25, a first power supply block 28 is slidably provided on the left end surface of the temperature insulation plate 12, the first power supply block 28 is located between the limit block 25 and the plug 29, a first spring 27 is fixedly provided between the first power supply block 28 and the limit block 25, an air pressure casing 71 is fixedly provided on the inner wall of the left side of the receiving cavity 11, an air pressure machine 17 is fixedly provided on the lower end surface of the air pressure casing 71, an, a push rod 20 is fixedly arranged on the upper end face of the air pressure cavity 18, the push rod 20 penetrates through the inner wall of the upper side of the air pressure cavity 18, a top block 21 is fixedly arranged on the upper end face of the push rod 20, a slide sheet 22 is fixedly arranged on the upper end face of the top block 21, a slide rheostat 23 is fixedly arranged on the upper end face of the air pressure casing 71, the slide rheostat 23 is positioned on the right side of the push rod 20, the right end face of the slide sheet 22 is attached to the left end face of the slide rheostat 23, a heating block 30 is fixedly arranged on the right end face of the heat insulation plate 12, the heating block 30, the plug 29, the slide rheostat 23 and the slide sheet 22 are connected through a first electric wire 24, one end of the first electric wire 24 is connected with the slide sheet 22, the other end of the first electric wire 24 is connected with the slide rheostat 23, the first spring 27 pushes the first power supply block 28 to slide, the piston 19 drives the ejector block 21 to move through the push rod 20, and the ejector block 21 drives the sliding sheet 22 to move;

the detection device is characterized in that a detection mechanism 81 is arranged in the containing cavity 11, the detection mechanism 81 comprises a detection box 31 fixedly arranged between the thermal insulation plate 12 and the inner wall of the upper side of the containing cavity 11, a detection cavity 32 is arranged in the detection box 31, a separation plate 33 is fixedly arranged on the inner wall of the upper side of the detection cavity 32, a mercury probe 45 is fixedly arranged on the lower end surface of the separation plate 33, a first motor 34 is fixedly arranged on the inner wall of the left side of the detection cavity 32, a first motor 34 is rotatably arranged on the right end, a first rotating shaft 35 penetrates through the left end surface and the right end surface of the separation plate 33, the right end surface of the first rotating shaft 35 is rotatably arranged on the inner wall of the right side of the detection cavity 32, a sector gear 36 and a fan blade 37 are fixedly arranged on the first rotating shaft 35, the sector gear 36 and the fan blade 37 are respectively positioned on the left side and the right side of the, the right end face of the detection box 31 is fixedly provided with a collection box 44, the upper end face of the filter plate 43 is provided with a scraper 42 in a sliding manner, the inner wall of the left side of the detection cavity 32 is fixedly provided with a fixed block 38, the fixed block 38 is positioned at the lower side of the first motor 34, the fixed block 38 is internally provided with a torsion groove 39, a torsion spring 72 is arranged between the inner walls of the torsion groove 39 in a rotating manner, the inner wall of the left side of the torsion groove 39 is provided with a second rotating shaft 40 in a rotating manner, the second rotating shaft 40 penetrates through the left and right end faces of the partition plate 33 and the scraper 42, the scraper 42 is internally connected with the second rotating shaft 40 through threads, a transmission gear 41 is fixedly arranged on the second rotating shaft 40, the transmission gear 41 is positioned at the left side of the partition plate 33, the sector gear 36 can be meshed with the transmission gear 41 when rotating, the first motor 34 drives, when the sector gear 36 rotates, the sector gear intermittently engages with the transmission gear 41 to intermittently drive the transmission gear 41 to rotate, and the transmission gear 41 drives the scraper 42 to slide and twist the torsion spring 72 through the threaded connection with the scraper 42;

the storage cavity 11 is internally provided with a pressure maintaining mechanism 82, the pressure maintaining mechanism 82 comprises a gas storage tank 61 fixedly arranged on the inner wall of the upper side of the storage cavity 11, the gas storage tank 61 is internally provided with a gas storage cavity 62, the inner wall of the lower side of the gas storage cavity 62 is fixedly provided with an air pump 63, a connecting plate 64 is fixedly arranged between the gas storage tank 61 and the collecting box 44, the left end surface of the gas storage tank 61 is fixedly provided with a stop 66, the stop 66 is provided with a connecting rod 67 in a sliding manner, the connecting rod 67 penetrates through the upper end surface and the lower end surface of the stop 66, the upper end surface and the lower end surface of the connecting rod 67 are respectively and fixedly provided with a second slide block 68 and a first slide block 65, the right end surfaces of the second slide block 68 and the first slide block 65 are both arranged on the left end surface of the gas storage tank 61 in a sliding manner, the left end surface of the gas storage tank 61 is, the air pressure pushes the first slider 65 to slide upwards, the first slider 65 pushes the second slider 68 to slide upwards through the connecting rod 67, and the second slider 68 slides upwards to press the second spring 70.

Beneficially, temperature-control mechanism 80 still includes accomodate the supporting seat 13 that chamber 11 downside inner wall slided and is equipped with, accomodate the fixed third motor 14 that is equipped with of chamber 11 left side inner wall, the motor 14 is located aerostatic press 17 downside, the rotation of motor 14 right-hand member is equipped with third pivot 15, third pivot 15 runs through terminal surface about heat insulating plate 12 with supporting seat 13 left end face, inside threaded connection through of supporting seat 13 third pivot 15, the fixed reel 16 that is equipped with in third pivot 15, reel 16 is located heat insulating plate 12 left side, reel 16 with first power supply piece 28 is connected through first string 26.

Advantageously, the detection mechanism 81 further comprises a liquid storage tank 46 fixedly arranged on the left inner wall of the containing chamber 11, the liquid storage tank 46 is positioned at the lower side of the detection tank 31, a fixing plate 59 is fixedly arranged between the liquid storage tank 46 and the detection tank 31, a sliding plate 58 is slidably provided between the fixed plate 59 and the left inner wall of the receiving chamber 11, a third motor 56 and a starter 55 are fixedly arranged on the upper end surface of the liquid storage tank 46, the third motor 56 and the starter 55 are respectively positioned on the left side and the right side of the plug 29, the upper end surface of the third motor 56 is rotatably provided with a fourth rotating shaft 57, the fourth rotating shaft 57 penetrates through the upper and lower end surfaces of the sliding plate 58, the sliding plate 58 is internally connected with the fourth rotating shaft 57 through threads, the left end surface of the thermal insulation plate 12 is fixedly provided with a second power supply block 53, the second power supply block 53, the actuator 55, the third motor 56 and the mercury probe 45 are connected by a second wire 60.

Beneficially, be equipped with stock solution chamber 47 in the liquid reserve tank 46, the fixed water pump 48 that is equipped with of the lower side inner wall of liquid reserve chamber 47, water pump 48 with detect chamber 32 downside inner wall and pass through water pipe 49 and connect, the right end face of liquid reserve tank 46 slides and is equipped with third slider 51, the fixed trigger 50 that is equipped with of liquid reserve tank 46 right end face, trigger 50 is located third slider 51 downside, be equipped with floating block 54 in detecting the chamber 32, floating block 54 with third slider 51 passes through second string 52 and connects.

Advantageously, the elastic force of the second spring 70 is greater than the weight of the second slider 68, the connecting rod 67 and the first slider 65, the floating block 54 is a light wood block, the liquid level in the detection chamber 32 is higher than the mercury probe 45, and the buoyancy of the floating block 54 is greater than the weight of the third slider 51.

In the initial state, the first spring 27 is in a compressed state, the torsion spring 72 is in a normal state, the second spring 70 is in a stretched state, the detection box 31 and the liquid storage box 46 have an acidic solution therein, and the gas storage box 61 has nitrogen therein.

When the color porcelain sintering machine is used, color porcelain is placed on the upper end face of the supporting seat 13, the first motor 14 is started, the first motor 14 drives the third rotating shaft 15 to rotate, the third rotating shaft 15 drives the reel 16 to rotate, the third rotating shaft 15 drives the supporting seat 13 to slide to the left through threaded connection with the supporting seat 13, the color porcelain is conveyed to the interior of the color porcelain sintering machine, when the reel 16 rotates, the first thin rope 26 is loosened, the first spring 27 pushes the first power supply block 28 to slide upwards, the plug 29 is inserted into the first power supply block 28, the circuit is electrified, the heating block 30 starts to heat and fire the color porcelain, meanwhile, the air pump 63 injects nitrogen to keep a certain air pressure to provide a proper sintering environment, as the sintering progresses, the internal air pressure increases, the air pressure pushes the first sliding block 65 to slide upwards, the first sliding block 65 pushes the second sliding block 68 to slide upwards through the connecting rod 67, the second sliding block 68 to press the second spring 70 upwards, the internal air escapes, the first motor, the first rotating shaft 35 drives the sector gear 36 and the fan blade 37 to rotate, escaped gas is sucked, meanwhile, the torque groove 39 senses that pressure is weakened, the air pump 63 is started to continue to inject nitrogen into the containing cavity 11 to keep air pressure, the sector gear 36 intermittently meshes with the transmission gear 41 when rotating, so that the transmission gear 41 is intermittently driven to rotate, the transmission gear 41 drives the scraper 42 to slide and twist the torsion spring 72 through threaded connection with the scraper 42, smoke filtered on the filter plate 43 is cleaned, gas is cooled and discharged, when mercury in glaze is not dispersed due to low sintering temperature, the mercury probe 45 cannot detect the existence of mercury in acid solution, the starter 55 starts the gas compressor 17, the gas compressor 17 drives the piston 19 to slide upwards, the piston 19 drives the ejector block 21 to slide upwards through the push rod 20, the ejector block 21 drives the slide sheet 22 to slide upwards, the access resistance of the slide rheostat 23 is reduced, so that the heating efficiency of the heating block, the sintering temperature is increased, when the mercury probe 45 detects that mercury exists in the acid solution, after sintering is completed, the third motor 56 is started, the third motor 56 drives the fourth rotating shaft 57 to rotate, the fourth rotating shaft 57 drives the sliding plate 58 to slide through meshing with the sliding plate 58, the solution is discharged, the floating block 54 falls down due to the discharge of the solution, the third sliding block 51 slides downwards to touch the trigger 50, the sliding plate 58 resets, and the water pump 48 transmits the solution in the liquid storage tank 46 into the detection cavity 32 through the water pipe 49 to replace the reacted solution.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a color porcelain sintering device according to mercury divergence regulation temperature, includes the organism, its characterized in that: a containing cavity is arranged in the machine body, a temperature control mechanism is arranged in the containing cavity, the temperature control mechanism comprises a temperature insulating plate fixedly arranged on the inner wall of the lower side of the containing cavity, a limiting block and a plug are fixedly arranged on the left end face of the temperature insulating plate, the plug is positioned on the upper side of the limiting block, a first power supply block is slidably arranged on the left end face of the temperature insulating plate, the first power supply block is positioned between the limiting block and the plug, a first spring is fixedly arranged between the first power supply block and the limiting block, an air pressure machine shell is fixedly arranged on the inner wall of the left side of the containing cavity, an air compressor is fixedly arranged on the lower end face of the air pressure machine shell, an air pressure cavity is arranged in the air pressure machine shell, a push rod is fixedly arranged on the upper end face of the air pressure cavity, the push rod penetrates through the inner wall of the upper side of the air pressure cavity, a top block is, the slide rheostat is positioned on the right side of the push rod, the right end face of the sliding piece is attached to the left end face of the slide rheostat, a heating block is fixedly arranged on the right end face of the heat insulation plate, the heating block, the plug, the slide rheostat and the sliding piece are connected through a first wire, one end of the first wire is connected with the sliding piece, and the other end of the first wire is connected with the slide rheostat;

2. The colored porcelain sintering device for adjusting temperature according to mercury divergence amount according to claim 1, characterized in that: temperature control mechanism still includes accomodate the supporting seat that chamber downside inner wall slided and is equipped with, accomodate the fixed third motor that is equipped with of chamber left side inner wall, the first motor is located the aerostatic press downside, the motor right-hand member rotates and is equipped with the third pivot, the third pivot runs through terminal surface about the thermal-insulated board with supporting seat left end face, inside threaded connection of passing through of supporting seat the third pivot, the fixed reel that is equipped with in the third pivot, the reel is located thermal-insulated board left side, the reel with first power supply piece is connected through first string.

3. The colored porcelain sintering device for adjusting temperature according to mercury divergence amount according to claim 1, characterized in that: the detection mechanism is still including fixed setting accomodate the liquid reserve tank of chamber left side inner wall, the liquid reserve tank is located the detection case downside, the liquid reserve tank with fixed plate that is equipped with between the detection case, the fixed plate with accomodate and slide between the chamber left side inner wall and be equipped with the sliding plate, the fixed third motor and the starter that is equipped with of liquid reserve tank up end, the third motor with the starter is located respectively the plug left and right sides, third motor up end rotates and is equipped with the fourth pivot, the fourth pivot runs through terminal surface about the sliding plate, the sliding plate is inside through threaded connection the fourth pivot, the fixed second power supply piece that is equipped with of partition temperature board left end face, the second power supply piece the third motor with the mercury probe passes through second connection of electric lines.

4. The colored porcelain sintering device for adjusting temperature according to mercury divergence amount according to claim 1, characterized in that: be equipped with the stock solution chamber in the liquid reserve tank, the fixed water pump that is equipped with of stock solution chamber downside inner wall, the water pump with it passes through the water piping connection to detect chamber downside inner wall, the slip of liquid reserve tank right-hand member face is equipped with the third slider, the fixed trigger that is equipped with of liquid reserve tank right-hand member face, the trigger is located the third slider downside, it is equipped with the floating block to detect the intracavity, the floating block with the third slider passes through the second string and connects.

5. The colored porcelain sintering device for adjusting temperature according to mercury divergence amount according to claim 1, characterized in that: the elasticity of the second spring is greater than the gravity of the second sliding block, the connecting rod and the first sliding block, the floating block is a light wood block, the liquid level in the detection cavity is higher than the mercury probe, and the buoyancy of the floating block is greater than the gravity of the third sliding block.