CN111618988B - Drying treatment device for ceramic processing - Google Patents

Abstract

A drying treatment device for ceramic processing, comprising: four corners of the bottom of the machine body frame are connected with supporting legs; the outer side surface of the machine body frame is connected with a bracket; the inner side surface of the bracket is provided with a reversing switch; the drying component is arranged in the machine frame; drive assembly, drive assembly are installed at organism frame top, and drive assembly is connected with the drying assembly transmission. According to the microwave drying device, the discharge conveyor belt can rotate anticlockwise after the isolating door is opened, and the discharge conveyor belt can convey dried ceramic blanks backwards by anticlockwise rotation, so that the dried ceramic blanks do not need to be manually taken out from the microwave emission frame one by one, and time and labor can be saved; and the dried ceramic body can also stay on the discharge conveyor belt for cooling, so that the hand can be prevented from being scalded when the ceramic body is taken down manually.

Description

Drying treatment device for ceramic processing

Technical Field

The present invention relates to a drying apparatus, and more particularly to a drying apparatus for ceramic processing.

Background

In order to finalize the design to ceramic body, prevent that ceramic body is cracked when firing, need dry ceramic body, generally manual putting into the drying-machine with ceramic body one by one at present and drying, the manual ceramic body after will drying is taken out from the drying-machine again, so waste time and energy, and ceramic body after the stoving has the heat, when the manual ceramic body after with drying is taken out from the drying-machine, the hand is easily scalded, can take the ceramic body after the stoving in order to prevent to be scalded the staff and take thicker gloves, but take the ceramic body of being not convenient for to take thicker gloves on.

Therefore, it is necessary to develop a drying treatment device for ceramic processing, which is capable of saving time and labor and preventing hands from being scalded.

Disclosure of Invention

The purpose of the invention is: provided is a drying treatment device for ceramic processing, which can save time and labor and prevent hands from being scalded.

The technical scheme provided by the invention is as follows: a drying treatment device for ceramic processing, comprising: four corners of the bottom of the machine body frame are connected with supporting legs; the outer side surface of the machine body frame is connected with a bracket; the inner side surface of the bracket is provided with a reversing switch; the drying component is arranged in the machine frame; drive assembly, drive assembly are installed at organism frame top, and drive assembly is connected with the drying assembly transmission.

Preferably, the drying assembly comprises: the microwave emission frame is arranged in the machine body frame; a plurality of electric hubs are arranged between the inner side surfaces of the microwave transmitting frames; the support is internally connected with an isolation door in a sliding manner; one side of the isolation door is connected with a pressure rod; a stop switch, wherein the upper part of one side of the machine body frame is provided with the stop switch.

Preferably, the drive assembly comprises: the top of the machine body frame is provided with the double-shaft motor, the double-shaft motor is electrically connected with the reversing switch, and the double-shaft motor is electrically connected with the stop switch; the two sides of the double-shaft motor are connected with the large gears; the two sides of the upper part of the isolating door are both connected with first racks, and the first racks are meshed with the large gear.

Preferably, the device further comprises a feeding assembly, wherein the feeding assembly comprises: the lower part of one side of the machine body frame is connected with the mounting frame; at least two first rollers are rotatably connected between the inner side surfaces of the mounting frames; the feeding conveyor belt is connected between the first rollers; one first roller is connected with a first rotating shaft; the first mounting block is connected to one side, close to the first rotating shaft, of the mounting frame; the first mounting block is rotatably connected with a first rotating shaft; the first belt is connected between the second rotating shaft and the first rotating shaft; the second rotating shaft is connected with a second bevel gear; a second bevel gear is rotatably connected to one side, close to the second rotating shaft, of the first mounting block, and the second bevel gear is meshed with the first bevel gear; the second bevel gear is connected with a first one-way gear; and the lower part of one side of the isolating door is connected with a second rack which is meshed with the first one-way gear.

Preferably, also include ejection of compact subassembly, ejection of compact subassembly includes: the lower part of the other side of the machine body frame is connected with a fixed frame; at least two second rollers are rotatably connected between the inner side surfaces of the fixing frames; the discharge conveyor belt is connected between the second rollers; one of the second rollers is connected with a third rotating shaft; one side of the fixing frame close to the third rotating shaft is connected with a second mounting block; the second mounting block is rotatably connected with a second rotating shaft; a second belt is connected between the fourth rotating shaft and the third rotating shaft; the fourth rotating shaft is connected with a third bevel gear; one side, close to the third bevel gear, of the second mounting block is rotatably connected with the fourth bevel gear, and the fourth bevel gear is meshed with the third bevel gear; the fourth bevel gear is connected with a second one-way gear; and the lower part of the other side of the machine body frame is connected with a third rack which is meshed with the second one-way gear.

Advantageous effects

1. According to the microwave drying device, the feeding conveyor belt can rotate anticlockwise after the isolating door is opened, and the ceramic blanks can be conveyed backwards by anticlockwise rotation of the feeding conveyor belt, so that the ceramic blanks do not need to be manually placed into the microwave emission frame one by one, time and labor can be saved, and the microwave emission frame can emit microwaves to dry the ceramic blanks;

2. according to the microwave drying device, the discharge conveyor belt can rotate anticlockwise after the isolating door is opened, and the discharge conveyor belt can convey dried ceramic blanks backwards by anticlockwise rotation, so that the dried ceramic blanks do not need to be manually taken out from the microwave emission frame one by one, and time and labor can be saved; and the dried ceramic body can also stay on the discharge conveyor belt for cooling, so that the hand can be prevented from being scalded when the ceramic body is taken down manually.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of the drying assembly and drive assembly of the present invention;

FIG. 3 is a schematic perspective view of the feed assembly of the present invention;

FIG. 4 is an enlarged view of portion A of the present invention;

fig. 5 is a schematic perspective view of the discharging assembly of the present invention.

In the figure: 1-support leg, 2-machine body frame, 3-support, 4-reversing switch, 5-drying component, 51-microwave emission frame, 52-isolation door, 53-electric hub, 54-pressure rod, 55-stop switch, 6-driving component, 61-double-shaft motor, 62-big gear, 63-first rack, 7-feeding component, 72-mounting rack, 73-feeding conveying belt, 74-first roller, 75-first rotating shaft, 76-first belt, 77-second rotating shaft, 78-first mounting block, 79-first bevel gear, 710-second bevel gear, 711-first one-way gear, 712-second rack, 8-discharging component, 82-mounting rack, 83-discharging conveying belt, 84-a second roller, 85-a third rotating shaft, 86-a second belt, 87-a second mounting block, 88-a fourth rotating shaft, 89-a third bevel gear, 810-a fourth bevel gear, 811-a second one-way gear, 812-a third rack and 100-a ceramic blank.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

The utility model provides a drying process device that ceramic machining used, as shown in fig. 1-3, including landing leg 1, organism frame 2, support 3, reversal switch 4, drying component 5 and drive assembly 6, both sides all are connected with two landing legs 1 around organism frame 2 bottom, the lateral surface of organism frame 2 is connected with support 3, reversal switch 4 is installed to the medial surface of support 3 front side, install drying component 5 in the organism frame 2, drive assembly 6 is installed at the top of organism frame 2, drive assembly 6 is connected with drying component 5 transmission.

Drying assembly 5 is including microwave emission frame 51, dodge gate 52, electronic wheel hub 53, depression bar 54 and stop switch 55, installs microwave emission frame 51 in organism frame 2, installs a plurality of electronic wheel hubs 53 between the medial surface of microwave emission frame 51 lower part, and support 3 internal sliding type is connected with dodge gate 52, and the left side sub-unit connection of dodge gate 52 leading flank has depression bar 54, and stop switch 55 is installed on the right side upper portion of organism frame 2 leading flank.

The driving assembly 6 comprises a double-shaft motor 61, a large gear 62 and a first rack 63, the double-shaft motor 61 is installed on the left side of the top of the machine body frame 2, the double-shaft motor 61 is electrically connected with the reversing switch 4, the double-shaft motor 61 is electrically connected with the stop switch 55, output shafts on the front side and the rear side of the double-shaft motor 61 are connected with the large gear 62, the front side and the rear side of the upper portion of the isolating door 52 are connected with the first rack 63, and the first rack 63 is meshed with the large gear 62.

Initially, the isolation door 52 blocks the microwave emission frame 51. When the ceramic body 100 is to be dried, the double-shaft motor 61 is manually started to enable the large gear 62 to rotate clockwise, the large gear 62 rotates clockwise to enable the first rack 63 to move leftwards, and the first rack 63 moves leftwards to drive the isolating door 52 to move leftwards. After the partition door 52 moves to the left for a certain distance, a plurality of ceramic blanks 100 can be manually placed on the electric hub 53 at the front side, then the electric hub 53 is started to rotate counterclockwise, so that the ceramic blanks 100 can move backwards, and after the ceramic blanks 100 move backwards to a proper position, the electric hub 53 is closed. The isolating door 52 moves leftwards to drive the pressure lever 54 to move leftwards, when the pressure lever 54 moves leftwards to be in contact with the reversing switch 4, the reversing switch 4 can be triggered, the reversing switch 4 can start the double-shaft motor 61 to enable the large gear 62 to rotate anticlockwise, the isolating door 52 can be reset rightwards, the isolating door 52 moves rightwards to reset and then is in contact with the stop switch 55, the stop switch 55 can be triggered, and the double-shaft motor 61 can be closed by the stop switch 55. After the isolation door 52 is reset, the microwave emission frame 51 is blocked again, then the microwave emission frame 51 is started manually to emit microwaves, the microwaves can dry the ceramic body 100, and after the ceramic body 100 is dried, the operation is repeated to take out the dried ceramic body 100.

Example 2

On the basis of embodiment 1, as shown in fig. 1, 3 and 4, the feeding device further includes a feeding assembly 7, the feeding assembly 7 includes a mounting frame 72, a feeding conveyor belt 73, first rollers 74, first rotating shafts 75, a first belt 76, a second rotating shaft 77, a first mounting block 78, a first bevel gear 79, a second bevel gear 710, a first one-way gear 711 and a second rack 712, the mounting frame 72 is connected to the right lower portion of the front side of the machine body frame 2, six first rollers 74 are rotatably connected between the inner side surfaces of the mounting frame 72, the feeding conveyor belt 73 is connected between the six first rollers 74, the first rotating shaft 75 is connected to the left end of the first roller 74 on the rear side, the first mounting block 78 is connected to the mounting frame 72 on the lower side of the first rotating shaft 75, the second rotating shaft 77 is rotatably connected to the first mounting block 78, the first belt 76 is connected between the second rotating shaft 77 and the first rotating shaft 75 through a belt pulley, the left end of the second rotating shaft 77 is connected with a first bevel gear 79, the first mounting block 78 at the rear side of the second rotating shaft 77 is rotatably connected with a second bevel gear 710, the second bevel gear 710 is engaged with the first bevel gear 79, the rear side of the transmission shaft of the second bevel gear 710 is connected with a first one-way gear 711, the right lower part of the front side surface of the isolating door 52 is connected with a second rack 712, and the second rack 712 is engaged with the first one-way gear 711.

When the ceramic green bodies 100 are to be dried, a plurality of ceramic green bodies 100 are first placed on the feeding conveyor belt 73 in order. The isolating door 52 moves left and right to drive the second rack 712 to move left and right, the second rack 712 can enable the first one-way gear 711 to rotate anticlockwise left, the first one-way gear 711 rotates anticlockwise to drive the second bevel gear 710 to rotate anticlockwise, the second bevel gear 710 rotates anticlockwise to enable the second rotating shaft 77 to rotate anticlockwise through the first bevel gear 79, the second rotating shaft 77 rotates anticlockwise to enable the first rotating shaft 75 to rotate anticlockwise through the first belt 76, the first rotating shaft 75 rotates anticlockwise to drive the first roller 74 at the rear side to rotate anticlockwise, and the first roller 74 rotates anticlockwise to enable the feeding conveyor belt 73 to rotate anticlockwise. The feeding conveyor belt 73 rotates anticlockwise to enable the ceramic body 100 on the feeding conveyor belt to move backwards, when the ceramic body 100 on the last side is about to enter the microwave emission frame 51, the electric hub 53 is started to rotate anticlockwise, so that the ceramic body 100 can move to the electric hub 53, the electric hub 53 rotates anticlockwise to enable the ceramic body 100 in the microwave emission frame 51 to move backwards, and when the ceramic body 100 in the microwave emission frame 51 moves backwards to a proper distance, the electric hub 53 is closed. When the second rack 712 moves leftward and is not engaged with the first one-way gear 711, the first one-way gear 711 stops rotating, so that the feeding conveyor belt 73 stops conveying the ceramic blank 100 backward, and when the second rack 712 moves rightward and is engaged with the first one-way gear 711, the second rack 712 continues to move rightward and the first one-way gear 711 does not rotate, so that the feeding conveyor belt 73 does not convey the ceramic blank 100 backward. Therefore, the isolating door 52 of the device can enable the feeding conveyor belt 73 to rotate anticlockwise after being opened, and the feeding conveyor belt 73 can convey the ceramic blanks 100 backwards in the anticlockwise rotation mode, so that the ceramic blanks 100 are not required to be manually placed into the microwave emission frame 51 one by one, and time and labor can be saved.

Example 3

On the basis of embodiment 2, as shown in fig. 1, 2 and 5, the discharging device further includes a discharging assembly 8, the discharging assembly 8 includes a fixing frame 82, a discharging conveyor belt 83, a second roller 84, a third rotating shaft 85, a second belt 86, a second mounting block 87, a fourth rotating shaft 88, a third bevel gear 89, a fourth bevel gear 810, a second one-way gear 811 and a third rack 812, the right lower portion of the rear side surface of the machine body frame 2 is connected with the fixing frame 82, four second rollers 84 are rotatably connected between the inner side surfaces of the fixing frame 82, the discharging conveyor belt 83 is connected between the four second rollers 84, the left end of the front second roller 84 is connected with the third rotating shaft 85, the second mounting block 87 is connected to the fixing frame 82 on the lower side of the third rotating shaft 85, the fourth rotating shaft 88 is rotatably connected to the second mounting block 87, the second belt 86 is connected between the fourth rotating shaft 88 and the third rotating shaft 85 through a belt pulley, the left end of the fourth rotating shaft 88 is connected with a third bevel gear 89, the second mounting block 87 on the left side of the third bevel gear 89 is rotatably connected with a fourth bevel gear 810, the fourth bevel gear 810 is meshed with the third bevel gear 89, the front side of the transmission shaft of the fourth bevel gear 810 is connected with a second one-way gear 811, the lower part of the right side of the rear side surface of the machine body frame 2 is connected with a third rack 812, and the third rack 812 is meshed with the second one-way gear 811.

After the isolation door 52 moves to a proper distance to the left, the electric hub 53 is started to rotate anticlockwise, so that the dried ceramic blank 100 in the microwave emission frame 51 can move backwards, and after the dried ceramic blank 100 moves backwards to the discharge conveyor belt 83, the electric hub 53 is closed. The isolation door 52 moves left and right to drive the third rack 812 to move left and right, the third rack 812 can enable the second one-way gear 811 to rotate anticlockwise left, the second one-way gear 811 rotates anticlockwise to drive the fourth bevel gear 810 to rotate anticlockwise, the fourth bevel gear 810 rotates anticlockwise to enable the fourth rotating shaft 88 to rotate anticlockwise through the third bevel gear 89, the fourth rotating shaft 88 rotates anticlockwise to enable the third rotating shaft 85 to rotate anticlockwise through the second belt 86, the third rotating shaft 85 rotates anticlockwise to drive the second roller 84 at the front side to rotate anticlockwise, the second roller 84 rotates anticlockwise to enable the discharging conveyor belt 83 to rotate anticlockwise, and the discharging conveyor belt 83 rotates anticlockwise to enable the ceramic green bodies 100 dried on the discharging conveyor belt to move backwards. When the third rack 812 moves leftwards to be not meshed with the second one-way gear 811, the second one-way gear 811 stops rotating along with the third rack 812, so that the discharge conveyor belt 83 stops conveying the ceramic blank 100 backwards, and when the third rack 812 moves rightwards to be meshed with the second one-way gear 811, the third rack 812 continues moving rightwards to move rightwards to be not rotated by the second one-way gear 811, so that the discharge conveyor belt 83 does not convey the dried ceramic blank 100 backwards; the ceramic body 100 after drying like this can stay on exit conveyor 83 and cool off, and after ceramic body 100 after drying on exit conveyor 83 cools off, the manual work is with ceramic body 100 after cooling take off can, so can prevent scalding the hand. Therefore, the discharge conveyor belt 83 can rotate anticlockwise after the isolating door 52 of the device is opened, and the discharge conveyor belt 83 can convey the dried ceramic blanks 100 backwards by anticlockwise rotation, so that the dried ceramic blanks 100 are not required to be manually taken out from the microwave emission frame 51 one by one, and time and labor can be saved; and the dried ceramic body 100 can stay on the discharge conveyor belt 83 for cooling, so that the hand can be prevented from being scalded when the ceramic body 100 is taken down manually.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, various changes, modifications and substitutions can be made without departing from the spirit of the present invention, and these are all within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (1)

1. A drying treatment device for ceramic processing, comprising:

four corners of the bottom of the machine body frame (2) are connected with supporting legs (1);

the outer side surface of the machine body frame (2) is connected with the bracket (3);

the inner side surface of the bracket (3) is provided with the reversing switch (4);

the drying component (5) is arranged in the machine body frame (2);

the top of the machine body frame (2) is provided with a driving component (6), and the driving component (6) is in transmission connection with the drying component (5);

the drying assembly (5) comprises:

the microwave emitting frame (51), the microwave emitting frame (51) is arranged in the machine body frame (2);

a plurality of electric hubs (53) are arranged between the inner side surfaces of the microwave transmitting frames (51);

the isolating door (52) is connected in the bracket (3) in a sliding manner;

one side of the isolation door (52) is connected with the pressure lever (54);

a stop switch (55), wherein the upper part of one side of the machine body frame (2) is provided with the stop switch (55);

the drive assembly (6) comprises:

the top of the machine body frame (2) is provided with the double-shaft motor (61), the double-shaft motor (61) is electrically connected with the reversing switch (4), and the double-shaft motor (61) is electrically connected with the stop switch (55);

the two sides of the double-shaft motor (61) are both connected with the large gear (62);

the two sides of the upper part of the isolating door (52) are both connected with first racks (63), and the first racks (63) are meshed with the large gear (62);

still include pay-off subassembly (7), pay-off subassembly (7) includes:

the lower part of one side of the machine body frame (2) is connected with the mounting frame (72);

at least two first rollers (74) are rotatably connected between the inner side surfaces of the mounting frames (72);

the feeding conveyor belt (73) is connected between the first rollers (74);

a first rotating shaft (75), wherein one first roller (74) is connected with the first rotating shaft (75);

the first mounting block (78) is connected to one side, close to the first rotating shaft (75), of the mounting frame (72);

the second rotating shaft (77) is rotatably connected to the first mounting block (78);

a first belt (76) is connected between the second rotating shaft (77) and the first rotating shaft (75);

the first bevel gear (79) is connected to the second rotating shaft (77);

the second bevel gear (710) is rotatably connected to one side, close to the second rotating shaft (77), of the first mounting block (78), and the second bevel gear (710) is meshed with the first bevel gear (79);

the first one-way gear (711) is connected to the second bevel gear (710);

the lower part of one side of the isolating door (52) is connected with a second rack (712), and the second rack (712) is meshed with the first one-way gear (711);

still include ejection of compact subassembly (8), ejection of compact subassembly (8) includes:

the lower part of the other side of the machine body frame (2) is connected with a fixed frame (82);

at least two second rollers (84) are rotatably connected between the inner side surfaces of the fixing frames (82);

the discharge conveyor belt (83) is connected between the second rollers (84);

a third rotating shaft (85), wherein one second roller (84) is connected with the third rotating shaft (85);

one side of the fixed frame (82) close to the third rotating shaft (85) is connected with the second mounting block (87);

the fourth rotating shaft (88) is rotatably connected to the second mounting block (87) through the fourth rotating shaft (88);

a second belt (86), wherein the second belt (86) is connected between the fourth rotating shaft (88) and the third rotating shaft (85);

the third bevel gear (89) is connected to the fourth rotating shaft (88);

the fourth bevel gear (810) is rotatably connected to one side, close to the third bevel gear (89), of the second mounting block (87), and the fourth bevel gear (810) is meshed with the third bevel gear (89);

the fourth bevel gear (810) is connected with a second one-way gear (811);

and the lower part of the other side of the machine body frame (2) is connected with a third rack (812), and the third rack (812) is meshed with a second one-way gear (811).

Images