CN115682671A - Ceramic product cleaning and drying device of integrated form - Google Patents

Abstract

The invention provides an integrated ceramic product cleaning and drying device, which belongs to the technical field of ceramic production machinery and comprises a drying device main body, wherein the drying device main body comprises a lower drying unit, a drying chamber unit and an upper drying unit, the bottom side in the drying chamber unit is connected with a pull-pull integrated drying table in a sliding manner, and one side in the drying chamber unit is provided with a temperature sensor. According to the invention, a plurality of ceramic units are integrated together through the drawing integrated drying table for drying operation without mutual influence, and the drawing operation table is convenient for ceramic loading and unloading and operation table cleaning, so that the working efficiency is improved; the ceramic surface is heated through 360-degree uniform-speed rotation of the upper drying unit and the lower drying unit, so that uniform drying is realized, and the drying quality is improved; a ceramic track graph is drawn through a plurality of distance sensors, and the intelligent cleaning end is intelligently controlled to clean the surface of the ceramic to prevent the ceramic from colliding.

Description

Ceramic product cleaning and drying device of integrated form

Technical Field

The invention relates to the technical field of ceramic production machinery, in particular to an integrated ceramic product cleaning and drying device.

Background

The pottery is a general name of pottery, stoneware and porcelain, and the ancient people refer to the pottery as Ou. It is made up by using natural clay and various natural minerals as main raw materials through the processes of pulverizing, mixing, forming and calcining.

The drying of ceramics is one of the very important processes in the production process of ceramics, and the quality defects of the ceramic products are mostly caused by improper drying, wherein a ceramic dryer is often used in the drying process of ceramics.

The patent with the application number of CN201921363653.0 provides a multilayer dryer for drying ceramics, when the multilayer dryer is used, the arrangement of a heating assembly realizes electric heating and blowing drying, reasonably facilitates electric energy, and solves the problem that the conventional ceramic dryer usually burns and heats fuels such as coal and wood, and the fuel combustion easily causes environmental pollution; the arrangement of the multilayer placing discs improves the efficiency of ceramic manufacture; the setting of rotation stoving subassembly is through reasonable transmission, can rotate step by step when making the pottery base dry, makes the pottery dry by fire and is heated evenly, realizes drying comprehensively, has improved the finished product quality in later stage.

Although this technique improves the efficiency of ceramic drying to some extent, several problems still remain. Firstly, the ceramics are not separated, so that the drying operation is easily influenced; secondly, the ceramic drying temperature is not uniform, so that the ceramic is easy to generate flaws, and the quality of the ceramic is influenced; thirdly, the drying temperature is not controllable, which causes a certain energy waste.

Therefore, it is necessary to provide an integrated cleaning and drying device for ceramic products.

Disclosure of Invention

In order to comprehensively solve the problems, particularly the defects in the prior art, the invention provides an integrated ceramic product cleaning and drying device which can comprehensively solve the problems. The invention can homogenize the drying temperature of the ceramic surface, improve the ceramic quality, and simultaneously intelligently control the temperature and prevent energy waste.

In order to achieve the purpose, the invention adopts the following technical means:

the invention provides an integrated ceramic product cleaning and drying device which comprises a drying device main body, wherein an operation table is installed on the side portion of the drying device main body, an MSP430F 149 single-chip microcomputer controller is arranged in the operation table, the drying device main body comprises a lower drying unit, a drying chamber unit and an upper drying unit, the lower drying unit is arranged at the bottom of the drying device main body, the drying chamber unit is installed at the upper portion of the lower drying unit, the upper drying unit is connected with the upper drying unit, the bottom side of the interior of the drying chamber unit is connected with a pull-pull integrated drying table in a sliding mode, a temperature sensor is installed on one side of the interior of the drying chamber unit, the temperature sensor is a heat-resistant thermocouple type temperature sensor, and the front portion of the drying chamber unit is connected with a closed door through a rotating shaft.

It should be noted that the lower drying unit and the upper drying unit are internally provided with the lower drying heat supply module and the upper drying heat supply module which rotate at a constant speed, and the rotation angle is 0-360 degrees, so that the ceramic surface is uniformly heated.

Further, a downward-turning door is arranged on the front side of the upper portion of the lower drying unit, a lower drying driving motor is installed inside the lower drying unit, the model of the lower drying driving motor is a YZR180L-8-15KW motor, and a lower driving rotating shaft is installed on the upper portion of the lower drying driving motor.

As shown in the accompanying drawings to the attached drawings, in the above embodiment, specifically, the upper portion of the lower driving rotating shaft is engaged with a lower transmission structure, one side of the lower transmission structure is connected with a lower driven rotating shaft, the lower drying driving motor and the lower driven rotating shaft are installed on the upper portion of the lower electric lifting shaft, and the lower driving rotating shaft and the upper portion of the lower driven rotating shaft are provided with lower drying heat supply modules.

Furthermore, a QHRFC680A-20 loop intelligent power controller I and a lower electric heating piece are arranged inside the lower drying and heat supplying module, the upper part of the lower drying and heat supplying module is communicated with a lower heat supplying U-shaped transmission rotating shaft, and a plurality of lower drying openings are formed in the inner side of the lower heat supplying U-shaped transmission rotating shaft.

Specifically, the lower drying driving motor starts to work, the lower drying driving motor drives the lower driving rotating shaft to rotate, the lower driving rotating shaft drives the lower driven rotating shaft to rotate through the lower transmission structure, the lower driving rotating shaft and the lower driven rotating shaft respectively drive the lower heat supply U-shaped transmission rotating shaft connected with the lower driving rotating shaft and rotate, and meanwhile, the lower electric heat supply part inside the lower drying heat supply module starts to be started and is sprayed out from the lower drying port to the ceramic bottom area through the lower heat supply U-shaped transmission rotating shaft.

In order to realize energy economy, the power of the electric heating element is controlled in real time by the power controller.

Furthermore, pull integrated form stoving platform bottom is provided with a plurality of fretwork formula stoving seats, pull integrated form stoving platform both sides are through electronic slider and drying chamber unit bottom sliding connection, fretwork formula stoving seat upper portion is provided with a plurality of stoving wind import.

In order to realize centralized drying of a plurality of ceramics and not influence each other, the ceramics are placed in a single independent hollow drying seat and are separately placed.

Further, an upper drying driving motor is installed inside the upper drying unit, the model of the upper drying driving motor is a YZR180L-8-15KW motor, and an upper driving rotating shaft is installed on the upper portion of the upper drying driving motor.

Further, go up initiative pivot upper portion meshing and be connected with transmission structure, it is connected with driven spindle to go up transmission structure one side, it installs in last driven swivel mount lower part to go up driven spindle, it is provided with stoving heat supply module to go up initiative pivot and last driven spindle lower part.

Furthermore, a QHRFC680A-20 loop intelligent power controller II and an upper heating piece are arranged inside the upper drying and heating module, the lower part of the upper drying and heating module is communicated with an upper heating U-shaped transmission rotating shaft, and a plurality of upper drying openings are formed in the inner side of the upper heating U-shaped transmission rotating shaft.

It should be specifically stated that, the upper drying driving motor starts to operate, the upper drying driving motor drives the upper driving rotating shaft to rotate, the upper driving rotating shaft drives the upper driven rotating shaft to rotate through the upper transmission structure, the upper driving rotating shaft and the upper driven rotating shaft respectively drive the upper heating U-shaped transmission rotating shaft connected with the upper driving rotating shaft and rotate, and meanwhile, the upper heating element inside the upper drying heating module starts to be started and is ejected to the upper area of the ceramic from the upper drying port through the upper heating U-shaped transmission rotating shaft.

In order to realize energy economy, the power of the power-on heating element is controlled in real time through the power controller II.

Further, it is connected with the clean end of intelligence through the arc spliced pole to go up heat supply U type transmission pivot one side, a plurality of distance sensor are installed to clean end upper portion one side of intelligence, distance sensor is LDM4X type laser sensor, the clean axle of electronic flexible of one-to-one is installed to the distance sensor lateral part, the cleaning brush is installed to electronic flexible clean axle front end, the cleaning brush bottom is provided with corresponding slope collecting box, slope collecting box rear portion intercommunication has total collection room, total collection room is pegged graft on electronic flexible clean epaxial portion, total collection room one side is provided with the handle.

Further, the intelligent cleaning end comprises the following steps:

(1) the intelligent cleaning end rotates at a constant speed along with the upper heat supply U-shaped transmission rotating shaft, the distance sensor detects different time t, and the distances L between different heights H on the upper heat supply U-shaped transmission rotating shaft and the ceramic being dried are obtained;

(2) the detection data is transmitted to an MSP430F 149 single-chip microcomputer controller arranged in the operating platform to be processed and drawn into a ceramic track diagram;

(3) an MSP430F 149 single-chip microcomputer controller arranged in the operating platform controls electric telescopic cleaning shafts corresponding to the distance sensors one by one to stretch according to a ceramic track diagram as shown in the figure so as to ensure that the cleaning brush just contacts with the surface of the ceramic and prevent the cleaning brush from colliding with the ceramic;

(4) the slope collecting box at the bottom of the cleaning brush enables clean impurities to flow into the total collecting chamber, and after the final drying operation is finished, the total collecting chamber is taken down from the electric telescopic cleaning shaft to be cleaned.

Compared with the prior art, the invention has the beneficial effects that:

1. the efficiency is improved. According to the invention, through the arrangement of the drawing integrated drying table, a plurality of ceramic units can be isolated and centralized together for drying operation without mutual influence, and the drawing type operating table is convenient for ceramic loading and unloading and operating table cleaning, so that the working efficiency is improved.

2. The drying quality is improved. According to the invention, the ceramic surface is heated through 360-degree uniform rotation of the upper/lower drying units, so that uniform heating and drying are realized, and the drying quality is improved.

3. Intelligent clean, prevent with ceramic collision. According to the invention, a ceramic track graph is drawn through a plurality of distance sensors, and the intelligent cleaning end is intelligently controlled to clean the ceramic surface so as to prevent collision with the ceramic.

3. The energy is saved. The invention senses the real-time temperature in the drying chamber unit through the temperature sensor, intelligently adjusts the heating power of the upper/lower drying heat supply module and avoids unnecessary energy waste.

Drawings

FIG. 1 is a schematic diagram of the present invention.

Fig. 2 is a schematic view and a partial enlarged view of an open structure of the present invention.

Fig. 3 is a front view and a partially enlarged view of the present invention.

Fig. 4 is a partial sectional view of a lower drying unit of the present invention.

Fig. 5 is an enlarged view of a portion of fig. 4 according to the present invention.

Fig. 6 is a schematic view of the internal structure of the lower drying unit according to the present invention.

Fig. 7 is a front view and a partially enlarged view of the inner structure of the lower drying unit according to the present invention.

Fig. 8 is a partial sectional view of an upper drying unit according to the present invention.

Fig. 9 is an enlarged view of a portion of fig. 8 at B according to the present invention.

Fig. 10 is a schematic view of the internal structure of the upper drying unit according to the present invention.

Fig. 11 is a front view and a partially enlarged view of the internal structure of the upper drying unit according to the present invention.

Fig. 12 is a schematic diagram of the intelligent cleaning end structure of the invention.

Figure 13 is a top view of the intelligent cleaning end of the present invention.

Fig. 14 is an enlarged view of a portion of fig. 12 at C in accordance with the present invention.

Fig. 15 is an enlarged partial view of fig. 12 at D in accordance with the present invention.

FIG. 16 is a graph of the ceramic trace of the present invention.

In the figure:

100. a drying device main body; 1. a lower drying unit; 2. a drying chamber unit; 3. an upper drying unit; 4. an operation table; 5. a closing door; 6. a downward-turning door; 7. drawing an integrated drying table; 8. a temperature sensor; 9. a lower drying drive motor; 10. an upper drying driving motor; 11. an intelligent cleaning end; 71. a hollow-out drying seat; 72. an electric slider; 711. a drying air inlet; 91. a lower driving rotating shaft; 92. a lower transmission structure; 93. a lower driven rotating shaft; 94. a lower electric lifting shaft; 95. a lower drying heat supply module; 96. a lower heat supply U-shaped transmission rotating shaft; 97. a lower drying port; 951. a first power controller; 952. a lower power supply part; 101. an upper driving rotating shaft; 102. an upper transmission structure; 103. an upper driven rotating shaft; 104. an upper drying heat supply module; 105. a driven swivel base; 106. an upper heat supply U-shaped transmission rotating shaft; 107. an upper drying port; 1041. a second power controller; 1042. electrifying the heating element; 111. a distance sensor; 112. an electric telescopic cleaning shaft; 113. a cleaning brush; 114. a slope collection box; 115. a total collection chamber; 116. a handle; 117. an arc-shaped connecting column; t-equipment running time; the height of the H-distance sensor 111 above the upper heat supply U-shaped transmission rotating shaft 106; l-distance sensor 111 is the distance from the ceramic.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

the embodiment is as follows:

as shown in fig. 1 to 9, the invention provides an integrated ceramic product cleaning and drying device, which comprises a drying device main body 100, wherein an operation table 4 is installed on a side portion of the drying device main body 100, an MSP430F 149 single-chip microcomputer controller is arranged inside the operation table 4, the drying device main body 100 comprises a lower drying unit 1, a drying chamber unit 2 and an upper drying unit 3, the lower drying unit 1 is arranged at the bottom of the drying device main body 100, the drying chamber unit 2 is installed at the upper portion of the lower drying unit 1, the upper drying unit 3 is connected to the upper portion of the drying chamber unit 2, a pull-pull integrated drying table 7 is connected to the bottom side of the inside of the drying chamber unit 2 in a sliding manner, a temperature sensor 8 is installed at one side of the inside of the drying chamber unit 2, the temperature sensor 8 is a heat-resistant thermocouple temperature sensor, and the front portion of the drying chamber unit 2 is connected with a sealing door 5 through a rotating shaft.

It should be noted that the lower drying heat supply module 95 and the upper drying heat supply module 104 in the lower drying unit 1 and the upper drying unit 3 rotate at a constant speed, and the rotation angle is 0 to 360 degrees, so as to uniformly heat the ceramic surface.

As shown in fig. 1 to 6, in the above embodiment, specifically, a downward-turning door 6 is disposed at a front side of an upper portion of the lower drying unit 1, a lower drying driving motor 9 is installed inside the lower drying unit 1, the model of the lower drying driving motor 9 is YZR180L-8-15KW type motor, and a lower driving rotating shaft 91 is installed at an upper portion of the lower drying driving motor 9.

As shown in fig. 4 to fig. 6, in the above embodiment, specifically, the upper portion of the lower driving rotating shaft 91 is engaged with a lower transmission structure 92, one side of the lower transmission structure 92 is connected with a lower driven rotating shaft 93, the lower drying driving motor 9 and the lower driven rotating shaft 93 are installed on the upper portion of the lower electric lifting shaft 94, and the lower drying heat supply module 95 is disposed on the upper portions of the lower driving rotating shaft 91 and the lower driven rotating shaft 93.

As shown in fig. 5 to fig. 7, in the above embodiment, specifically, a QHRFC680A-20 loop intelligent power controller first 951 and a lower electric heating element 952 are arranged inside the lower drying and heating module 95, the upper portion of the lower drying and heating module 95 is communicated with a lower heating U-shaped transmission rotating shaft 96, and a plurality of lower drying ports 97 are arranged inside the lower heating U-shaped transmission rotating shaft 96.

It should be specifically described that, the lower drying driving motor 9 starts to work, the lower drying driving motor 9 drives the lower driving rotating shaft 91 to rotate, the lower driving rotating shaft 91 drives the lower driven rotating shaft 93 to rotate through the lower transmission structure 92, the lower driving rotating shaft 91 and the lower driven rotating shaft 93 respectively drive the lower heat supply U-shaped transmission rotating shaft 96 connected thereto to rotate, and meanwhile, the lower electric heat supply member 952 inside the lower drying heat supply module 95 starts to be started and is ejected to the ceramic bottom area from the lower drying port 97 through the lower heat supply U-shaped transmission rotating shaft 96.

In order to realize energy economy, the power of the electric heating element 952 is controlled in real time by the first power controller 951.

As shown in fig. 2 to 7, in the above embodiment, specifically, a plurality of hollowed-out drying seats 71 are disposed at the bottom of the pull-out integrated drying table 7, two sides of the pull-out integrated drying table 7 are slidably connected to the bottom of the drying chamber unit 2 through electric sliding blocks 72, and a plurality of drying air inlets 711 are disposed at the upper portion of the hollowed-out drying seats 71.

In order to realize centralized drying of a plurality of ceramics without mutual influence, the ceramics are placed in a single independent hollow drying seat 71 and are separately placed.

As shown in fig. 8 to 10, in the above embodiment, specifically, upper drying driving motor 10 is installed inside upper drying unit 3, model of upper drying driving motor 10 is YZR180L-8-15KW type motor, and upper driving shaft 101 is installed on upper portion of upper drying driving motor 10.

As shown in fig. 9 to 10, in the above embodiment, specifically, an upper transmission structure 102 is engaged with an upper portion of the upper driving rotation shaft 101, an upper driven rotation shaft 103 is connected to one side of the upper transmission structure 102, the upper driven rotation shaft 103 is mounted at a lower portion of the upper driven rotation base 105, and an upper drying and heat supplying module 104 is disposed at a lower portion of the upper driving rotation shaft 101 and the upper driven rotation shaft 103.

As shown in fig. 9 to fig. 11, in the above embodiment, specifically, a QHRFC680A-20 loop intelligent power controller ii 1041 and an upper electric heating element 1042 are arranged inside the upper drying and heating module 104, the lower portion of the upper drying and heating module 104 is communicated with an upper heating U-shaped transmission rotating shaft 106, and a plurality of upper drying ports 107 are arranged inside the upper heating U-shaped transmission rotating shaft 106.

Specifically, the upper drying driving motor 10 starts to work, the upper drying driving motor 10 drives the upper driving rotating shaft 101 to rotate, the upper driving rotating shaft 101 drives the upper driven rotating shaft 103 to rotate through the upper transmission structure 102, the upper driving rotating shaft 101 and the upper driven rotating shaft 103 respectively drive the upper heat supply U-shaped transmission rotating shaft 106 connected thereto to rotate, and meanwhile, the upper electric heating element 1042 inside the upper drying and heat supplying module 104 starts to start and is ejected to the ceramic upper area from the upper drying port 107 through the upper heat supply U-shaped transmission rotating shaft 106.

In order to realize energy economy, the power of the upper electric heating element 1042 is controlled in real time by the second power controller 1041.

As shown in fig. 10 to 15, in the above embodiment, specifically, one side of the upper heat supply U-shaped transmission rotation shaft 106 is connected to the intelligent cleaning end 11 through an arc-shaped connection column 117, one side of the upper portion of the intelligent cleaning end 11 is provided with a plurality of distance sensors 111, the distance sensors 111 are LDM4X laser sensors, one-to-one corresponding electric telescopic cleaning shafts 112 are mounted on the side portions of the distance sensors 111, the front ends of the electric telescopic cleaning shafts 112 are provided with cleaning brushes 113, the bottoms of the cleaning brushes 113 are provided with corresponding slope collection boxes 114, the rear portions of the slope collection boxes 114 are communicated with a main collection chamber 115, the main collection chamber 115 is inserted into the upper portion of the electric telescopic cleaning shafts 112, and one side of the main collection chamber 115 is provided with a handle 116.

As shown in fig. 10 to 16, in the above embodiment, in particular, the intelligent cleaning end 11 has the following steps:

(1) the intelligent cleaning end 11 rotates at a constant speed along with the upper heat supply U-shaped transmission rotating shaft 106, the distance sensor 111 detects the distances L between the ceramic being dried and the upper heat supply U-shaped transmission rotating shaft 106 at different heights H at different times t;

(2) transmitting the detection data to an MSP430F 149 single-chip microcomputer controller arranged inside the operation table 4, processing and drawing a ceramic track diagram as shown in FIG. 12;

(3) an MSP430F 149 single-chip microcomputer controller arranged in the operating platform 4 controls the electric telescopic cleaning shafts 112 corresponding to the distance sensors 111 one by one to extend and retract according to a ceramic track diagram as shown in FIG. 12, so that the cleaning brush 113 is ensured to be just contacted with the ceramic surface and prevented from colliding with the ceramic;

(4) the cleaned foreign materials flow into the main collecting chamber 115 through the slope collecting box 114 at the bottom of the cleaning brush 113, and after the final drying operation is completed, the main collecting chamber 115 is removed from the electric telescopic cleaning shaft 112 to be cleaned.

Principle of operation

When the invention is used, a user opens the closing door 5, and the pull-type integrated drying table 7 is controlled by the operating table 4 to automatically slide out of the drying chamber unit 2 at a constant speed through the electric sliding block 72.

Then, the user places the ceramics to be dried in the hollow-out type drying seat 71 at the bottom of the drawing integrated type drying table 7 in sequence, so that the centralized and unitized isolation placement of a plurality of ceramics is realized, and the drawing integrated type drying table 7 is controlled to recover to the original position after the placement is finished.

Then, the control device is started through the operation table 4, and the lower electric lifting shaft 94 lifts the lower heat supply U-shaped transmission rotating shaft 96 to be flush with the hollow drying seat 71. Lower stoving driving motor 9 and last stoving driving motor 10 begin work, lower stoving driving motor 9 drives down initiative pivot 91 and rotates, lower initiative pivot 91 drives driven shaft 93 through lower transmission structure 92 and rotates down, lower initiative pivot 91 and lower driven shaft 93 drive respectively rather than the lower heat supply U type transmission pivot 96 of being connected and rotate, the inside lower electric heat supply 952 of lower stoving heat supply module 95 begins to start simultaneously, and spout ceramic bottom region from lower stoving mouth 97 via lower heat supply U type transmission pivot 96, the regional heating drying of ceramic upper portion can be accomplished to last stoving heat supply module 104 in the same reason, with this realization to ceramic surface at the uniform velocity heating stoving, improve the mesh of stoving effect.

When the drying operation is performed, the temperature sensor 8 installed at one side inside the drying chamber unit 2 starts to detect the temperature information inside the drying chamber unit 2 synchronously and transmits the temperature information to the MSP430F 149 single-chip microcomputer controller arranged inside the operation console 4 for analysis, when the temperature is low, the first power controller 951 and the second power controller 1041 are controlled to increase the output power of the lower electric heating unit 952 and the upper electric heating unit 1042 and increase the internal temperature of the drying chamber unit 2, and when the temperature is low, the first power controller 951 and the second power controller 1041 are controlled to reduce the output power of the lower electric heating unit 952 and the upper electric heating unit 1042 and reduce the internal temperature of the drying chamber unit 2, so that the purposes of intelligently controlling the drying temperature and reducing the energy consumption are achieved.

During cleaning operation, the intelligent cleaning end 11 rotates at a constant speed along with the upper heat supply U-shaped transmission rotating shaft 106, the distance sensor 111 detects different time t, and the distance L between the ceramic being dried and the ceramic at different heights H on the upper heat supply U-shaped transmission rotating shaft 106. The detection data is transmitted to an MSP430F 149 single-chip microcomputer controller arranged inside the operation table 4 to be processed and drawn into a ceramic track diagram as shown in FIG. 12. The MSP430F 149 single-chip microcomputer controller arranged inside the operating table 4 controls the electric telescopic cleaning shafts 112 corresponding to the distance sensors 111 one by one to be telescopic according to the ceramic track diagram as shown in fig. 12, so that the cleaning brush 113 is just in contact with the ceramic surface and is prevented from colliding with the ceramic. The cleaned impurities are flowed into the main collecting chamber 115 through the slope collecting box 114 at the bottom of the cleaning brush 113, and after the final drying operation is completed, the main collecting chamber 115 is removed from the electric telescopic cleaning shaft 112 for cleaning.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, are used in the orientations and positional relationships indicated in the drawings, which are based on the orientations and positional relationships indicated in the drawings, and are used for convenience of description and simplicity of description, but do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a ceramic product cleaning and drying device of integrated form, includes drying device main part (100), operation panel (4) are installed to drying device main part (100) lateral part, operation panel (4) inside is provided with MSP430F 149 single chip microcomputer controller, its characterized in that: drying device main part (100) are including drying unit (1), drying chamber unit (2) and last drying unit (3) down, drying device main part (100) bottom is provided with down drying unit (1), drying chamber unit (2) are installed on drying unit (1) upper portion down, drying chamber unit (2) upper portion is connected with drying unit (3), the inside bottom side sliding connection of drying chamber unit (2) has pull integrated form stoving platform (7), temperature-sensing ware (8) are installed to inside one side of drying chamber unit (2), temperature-sensing ware (8) are heat-resisting type thermocouple formula temperature sensor, drying chamber unit (2) front portion is connected with closed door (5) through the pivot.

2. The integrated ceramic product cleaning and drying device according to claim 1, wherein a lower turnover door (6) is provided at a front side of an upper portion of the lower drying unit (1), a lower drying driving motor (9) is installed inside the lower drying unit (1), the lower drying driving motor (9) is a YZR180L-8-15KW type motor, and a lower driving rotating shaft (91) is installed at an upper portion of the lower drying driving motor (9).

3. The integrated ceramic product cleaning and drying device as claimed in claim 2, wherein a lower transmission structure (92) is engaged with an upper portion of the lower driving rotation shaft (91), a lower driven rotation shaft (93) is connected to one side of the lower transmission structure (92), the lower drying driving motor (9) and the lower driven rotation shaft (93) are mounted on an upper portion of the lower electric lifting shaft (94), and a lower drying heat supply module (95) is disposed on upper portions of the lower driving rotation shaft (91) and the lower driven rotation shaft (93).

4. The integrated ceramic product cleaning and drying device as claimed in claim 3, wherein a QHRFC680A-20 loop intelligent power controller (951) and a lower electric heating element (952) are disposed inside the lower drying and heating module (95), a lower heating U-shaped transmission shaft (96) is connected to an upper portion of the lower drying and heating module (95), and a plurality of lower drying ports (97) are disposed inside the lower heating U-shaped transmission shaft (96).

5. The integrated ceramic product cleaning and drying device according to claim 1, wherein a plurality of hollowed-out drying seats (71) are arranged at the bottom of the pull-out integrated drying table (7), two sides of the pull-out integrated drying table (7) are slidably connected with the bottom of the drying chamber unit (2) through electric sliding blocks (72), and a plurality of drying air inlets (711) are arranged at the upper part of the hollowed-out drying seats (71).

6. An integrated ceramic product cleaning and drying device according to claim 1, wherein the upper drying unit (3) is internally provided with an upper drying driving motor (10), the upper drying driving motor (10) is a YZR180L-8-15KW type motor, and the upper driving shaft (101) is arranged on the upper part of the upper drying driving motor (10).

7. An integrated ceramic product cleaning and drying device as claimed in claim 6, wherein the upper driving shaft (101) is engaged with the upper transmission structure (102) at the upper portion, the upper driven shaft (103) is connected to one side of the upper transmission structure (102), the upper driven shaft (103) is mounted at the lower portion of the upper driven rotary base (105), and the upper drying and heat supplying module (104) is disposed at the lower portions of the upper driving shaft (101) and the upper driven shaft (103).

8. The integrated ceramic product cleaning and drying device according to claim 7, wherein a QHRFC680A-20 loop intelligent power controller two (1041) and an upper heating element (1042) are disposed inside the upper drying and heating module (104), an upper heating U-shaped transmission rotating shaft (106) is communicated with a lower portion of the upper drying and heating module (104), and a plurality of upper drying ports (107) are disposed inside the upper heating U-shaped transmission rotating shaft (106).

9. The integrated cleaning and drying device for the ceramic products as claimed in claim 8, wherein one side of the upper heat supply U-shaped transmission rotating shaft (106) is connected with the intelligent cleaning end (11) through an arc-shaped connecting column (117), one side of the upper portion of the intelligent cleaning end (11) is provided with a plurality of distance sensors (111), the distance sensors (111) are LDM 4X-type laser sensors, the side portions of the distance sensors (111) are provided with one-to-one corresponding electric telescopic cleaning shafts (112), the front ends of the electric telescopic cleaning shafts (112) are provided with cleaning brushes (113), the bottoms of the cleaning brushes (113) are provided with corresponding slope collecting boxes (114), the rear portions of the slope collecting boxes (114) are communicated with a main collecting chamber (115), the main collecting chamber (115) is inserted into the upper portion of the electric telescopic cleaning shafts (112), and one side of the main collecting chamber (115) is provided with a handle (116).

10. The integrated ceramic product cleaning and drying device according to claim 9, wherein the intelligent cleaning end (11) uses the following steps:

(1) the intelligent cleaning end (11) rotates at a constant speed along with the upper heat supply U-shaped transmission rotating shaft (106), the distance sensor (111) detects different time T, and the distances L between different heights H on the upper heat supply U-shaped transmission rotating shaft (106) and the ceramic being dried;

(2) transmitting the detection data to an MSP430F 149 single-chip microcomputer controller arranged inside the operating platform (4) for processing and drawing a ceramic track diagram as shown in FIG. 12;

(3) an MSP430F 149 single-chip microcomputer controller arranged in the operating platform (4) controls electric telescopic cleaning shafts (112) which correspond to the distance sensors (111) one by one to extend according to a ceramic track diagram as shown in figure 12, so that the cleaning brush (113) is ensured to be just contacted with the surface of the ceramic, and the ceramic is prevented from colliding;

(4) clean impurities flow into a main collecting chamber (115) through a slope collecting box (114) at the bottom of a cleaning brush (113), and after the final drying operation is finished, the main collecting chamber (115) is taken down from an electric telescopic cleaning shaft (112) for cleaning.

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