CN111319120A - Bowl mouth seals glaze mechanism based on ceramic manufacture - Google Patents

Abstract

The invention provides a bowl opening glaze sealing mechanism based on ceramic production, relates to the technical field of ceramic production, and solves the problems that in the existing process of sealing glaze on a ceramic bowl opening, only one ceramic bowl can be simultaneously sealed, and only one ceramic bowl can be simultaneously sealed, so that the replacement operation of the ceramic bowl opening glaze sealing ceramic bowl and the ceramic bowl to be sealed can be completed by one person, and the efficiency of the ceramic bowl opening glaze sealing operation is low. The bowl opening glaze sealing mechanism based on ceramic production comprises a supporting table, wherein a driving mechanism is installed on the left side of the supporting table, and a transmission mechanism in transmission fit with the driving mechanism is installed at the center of the top end of the supporting table. When the ceramic bowl feeding device is applied, the ceramic bowl is fed intermittently, so that the ceramic bowl sealing operation by workers at the front side of the supporting table is facilitated, and the mutual replacement of the ceramic bowl with the glaze sealing at the bowl opening and the ceramic bowl to be glazed at the bowl opening is facilitated by workers at the rear side of the supporting table.

Description

Bowl mouth seals glaze mechanism based on ceramic manufacture

Technical Field

The invention belongs to the technical field of ceramic production, and particularly relates to a bowl opening glaze sealing mechanism based on ceramic production.

Background

The ceramic is various products of materials prepared by crushing, mixing, molding and calcining natural clay and various natural minerals serving as main raw materials, and the ceramic bowl is used as a daily necessary diet utensil of people, and the production capacity of the ceramic bowl is the highest in the ceramic products.

In the production process of the ceramic bowl, the operation steps of the ceramic bowl opening glaze sealing procedure are complicated and the efficiency is low, and the operation steps are as follows: the staff takes up the ceramic bowl of treating bowl mouth to seal glaze and just puts on rotating equipment, then the handheld instrument that is stained with the frit contacts ceramic bowl mouth position, under rotating equipment's drive for ceramic bowl mouth is along being stained with the instrument rotation of frit, thereby realizes the glaze sealing operation to ceramic bowl mouth, and after ceramic bowl mouth seals glaze and finishes, the staff takes off this ceramic bowl from rotating equipment, puts another ceramic bowl of treating bowl mouth to seal glaze on rotating equipment again, repeats above-mentioned glaze sealing operation.

As mentioned above, the following defects exist in the operation steps of the ceramic bowl opening glaze sealing: the glaze sealing operation can be carried out on one ceramic bowl at the same time, and the glaze sealing operation can be carried out on one ceramic bowl at the same time, so that the glaze sealing operation of the bowl opening of the ceramic bowl and the glaze sealing operation of the ceramic bowl to be sealed can be finished by a single person, the efficiency of the glaze sealing operation of the bowl opening of the ceramic bowl is low, and the production of the ceramic bowl is greatly influenced.

Disclosure of Invention

In order to solve the technical problems, the invention provides a bowl opening glaze sealing mechanism based on ceramic production, which aims to solve the problems that in the existing ceramic bowl opening glaze sealing process, only one ceramic bowl can be simultaneously sealed, and only one ceramic bowl can be simultaneously sealed, so that the replacement operation of the ceramic bowl opening glaze sealing ceramic bowl and the ceramic bowl to be bowl opening glaze sealed can be completed by one person, and the efficiency of the ceramic bowl opening glaze sealing operation is low.

The invention relates to a bowl opening glaze sealing mechanism based on ceramic production, which is achieved by the following specific technical means:

a bowl mouth glaze sealing mechanism based on ceramic production comprises a supporting table, wherein a driving mechanism is arranged on the left side of the supporting table, and a transmission mechanism in transmission fit with the driving mechanism is arranged in the center of the top end of the supporting table; the supporting table comprises a circular bottom plate, supporting legs, supporting columns A, an annular block A, extending blocks, a glaze trough, bearings A, an annular groove A and balls A, wherein the bottom end of the circular bottom plate is fixedly connected with four supporting legs in an annular array shape, the annular block A in a coaxial line state with the circular bottom plate is arranged above the circular bottom plate, the bottom end face of the annular block A is fixedly connected with the top end face of the circular bottom plate through six supporting columns A which are distributed in an annular array shape, the extending block is arranged on the right side in front of the annular block A, the top end face of the extending block is provided with one glaze trough, one bearing A is embedded in the left side of the top end face of the circular bottom plate, the annular groove A is formed in the inner peripheral surface of the annular block A, and the top surface and the bottom surface of the inner end of the embedded annular groove A; the top end of the transmission mechanism is provided with a transmission auxiliary mechanism which is coaxial with the transmission mechanism, and the transmission auxiliary mechanism is meshed with the transmission mechanism and is in transmission fit with the transmission mechanism; six groups of bearing mechanisms are mounted on the top end face of the transmission auxiliary mechanism in an annular array shape, and the bearing mechanisms are in meshing transmission fit with the transmission mechanism.

Further, the driving mechanism comprises a motor A, a rotating shaft A, a circular block, a circular limiting block, an arc-shaped groove and a toggle column, wherein the bottom end of the rotating shaft A is fixedly connected with the motor A, the top end of the motor A is fixedly connected with the circular block which has the same axle center with the motor A, the axle center part of the top end face of the circular block is fixedly connected with the circular limiting block, the outer peripheral surface of the circular limiting block is provided with the arc-shaped groove, the top end face of the circular block is fixedly connected with the toggle column relative to the arc-shaped groove part, the rotating shaft A is fixedly connected with a bearing A in the installation state of the driving mechanism, and the motor A is fixedly connected to;

further, the transmission mechanism comprises a circular transmission plate, a cylinder A, a bearing B, a distribution box, a grooved pulley, a U-shaped toggle groove, a limit arc-shaped groove, an annular arc-shaped chute A, a support column B, an annular block B, a support column C, an annular groove B, an annular inner rack, a ball B and an annular arc-shaped chute B, wherein the axis part of the bottom end surface of the circular transmission plate is fixedly connected with the cylinder A, the bottom end surface of the cylinder A is fixedly connected with the grooved pulley which has the same axis with the cylinder A, the periphery of the grooved pulley is in an annular array shape and is provided with six U-shaped toggle grooves and six limit arc-shaped grooves, the six U-shaped toggle grooves and the six limit arc-shaped grooves are distributed at intervals, the right side of the top end surface of the circular transmission plate is embedded with the bearing B, the distribution box is arranged on the right side of the bottom end surface of the circular transmission plate, the adjacent edge parts of the top, an annular block B which is coaxial with the circular transmission plate is arranged right above the circular transmission plate, the bottom end face of the annular block B is fixedly connected with the top end face of the circular transmission plate through six support columns B which are distributed in an annular array shape, an annular groove B is formed in the inner peripheral surface of the annular block B, annular arc-shaped sliding grooves B are formed in the top surface and the bottom surface of the inner end of the annular groove B, an annular inner rack is arranged in the annular groove B, a plurality of balls B are embedded and rotatably installed on the bottom end face and the top end face of the annular inner rack in an annular array shape, the balls B which are embedded and rotatably installed on the bottom end face and the top end face of the annular inner rack are respectively and slidably connected into the two annular arc-shaped sliding grooves B, the top end of the annular block B is in an annular array shape and is fixedly connected with six support columns C, and the circular transmission plate is positioned in, the outer end face of the circular transmission plate is not contacted with the inner end face of the annular groove A, the ball A is connected in the annular arc-shaped sliding groove A in a sliding mode, the limiting arc-shaped groove is connected in a tangential sliding mode in the circular limiting block, and the toggle column is matched with the U-shaped toggle groove in a transmission mode;

further, the transmission auxiliary mechanism comprises a circular plate, a bearing C, a bearing D, a rotating shaft B, a motor B, a cylinder B, a bearing E, a transmission gear and a driving gear, wherein the top end of the circular plate is in an annular array shape and is embedded with six bearings C, the right side of the top end face of the circular plate is embedded with one bearing D, the bearing D is internally and fixedly connected with one rotating shaft B, the top end face of the rotating shaft B and the top end face of the circular plate are positioned on the same horizontal plane, the bottom end of the rotating shaft B is fixedly connected with the motor B, the rotating shaft B is fixedly connected with one driving gear, the bottom end face of the circular plate is positioned on the right side of the bearing D and is fixedly connected with one cylinder B, the bottom end of the cylinder B is fixedly connected with one transmission gear through the bearing E, the transmission gear and the driving gear, in the installation state of the transmission auxiliary mechanism, the bottom end face of the circular plate is fixedly connected with the top end face of the support column C, the rotating shaft B is fixedly connected with the bearing B, the motor B is fixedly connected with the bottom end face of the circular transmission plate, the motor B is electrically connected with the distribution box, and the transmission gear is meshed with the annular inner rack;

further, the bearing mechanism comprises a bearing disc, a circular protrusion, a rotating shaft B, a driven gear and a rubber layer, wherein the axis part of the bottom end face of the bearing disc is provided with the circular protrusion, the axis part of the bottom end face of the circular protrusion is fixedly connected with the rotating shaft B, the bottom end of the rotating shaft B is fixedly connected with the driven gear, the rubber layer is bonded on the top end face of the bearing disc, the circular protrusion is fixedly connected with the bearing C in the installation state of the bearing mechanism, and the driven gear is meshed with the annular inner rack;

compared with the prior art, the invention has the following beneficial effects:

when the ceramic bowl glaze device is applied, one worker at the front side of the supporting platform can add glaze into the glaze material groove, the other worker at the rear side of the supporting platform can sequentially place six ceramic bowls to be glaze-sealed at the bowl openings on the bearing discs in the six groups of bearing mechanisms respectively, the transmission auxiliary mechanism is meshed with the transmission annular inner rack through the transmission gear to rotate along the annular groove B, so that the driven gears in the six groups of bearing mechanisms meshed with the annular inner rack are transmitted to synchronously rotate, the six groups of bearing mechanisms respectively rotate along the bearing C to realize the rotation of the ceramic bowls, meanwhile, the driving mechanism drives the grooved pulley to rotate, the circular transmission plate rotates along the annular groove A through the sliding fit of the annular arc-shaped sliding groove A and the ball A, and simultaneously drives the transmission auxiliary mechanism fixedly connected with the limiting transmission mechanism to rotate, so as to drive the six groups of bearing mechanisms fixedly arranged on the transmission auxiliary mechanism to rotate together, make six groups of bearing mechanism feed one on the transmission complementary unit of fixed mounting, realize the intermittent type formula of ceramic bowl and feed, the staff that both is convenient for lie in brace table front side to the glaze sealing operation of ceramic bowl, also be convenient for lie in brace table rear side's staff realizes accomplishing bowl mouth seals glaze ceramic bowl and treats bowl mouth and seals the change each other of glaze ceramic bowl to the production efficiency of ceramic bowl seal glaze has been improved.

Drawings

Fig. 1 is a schematic front view of the present invention.

Fig. 2 is a schematic axial view of the present invention.

Fig. 3 is a schematic top view of the present invention.

FIG. 4 is a schematic view of the top end of the support table of the present invention.

FIG. 5 is a schematic bottom axial view of the support table of the present invention.

FIG. 6 is a schematic cross-sectional view of a support stage according to the present invention.

Fig. 7 is a front view of the driving mechanism of the present invention.

Fig. 8 is a schematic axial view of the drive mechanism of the present invention.

Fig. 9 is a schematic structural view of the support table and the driving mechanism of the present invention in a mounted state.

Fig. 10 is a schematic view of the internal cross-section of the transmission mechanism of the present invention.

Fig. 11 is a partially enlarged view of a portion a of fig. 10 according to the present invention.

Fig. 12 is a schematic structural view of the ring-shaped inner rack of fig. 10 in a state where the ring-shaped inner rack is removed, according to the present invention.

FIG. 13 is a schematic cross-sectional view B-B of FIG. 12 in accordance with the present invention.

Fig. 14 is a schematic view of the structure of the annular internal rack of the present invention.

Fig. 15 is a top axial view of the transmission mechanism of the present invention.

Fig. 16 is a bottom end axial view of the transmission mechanism of the present invention.

Fig. 17 is a schematic structural view of the circular limiting block and the sheave of the present invention in a fitted state.

FIG. 18 is a top axial view of the drive assist mechanism of the present invention.

FIG. 19 is a bottom end axial view of the drive assist mechanism of the present invention.

Fig. 20 is a front view schematically showing the structure of the transmission auxiliary mechanism of the present invention.

Fig. 21 is a schematic structural diagram of the bearing mechanism of the present invention.

FIG. 22 is a schematic structural diagram of the annular inner rack, the transmission gear, the driving gear and the driven gear of the present invention in a meshed state.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a support table; 101. a circular base plate; 102. supporting legs; 103. a support pillar A; 104. a ring block A; 105. an extension block; 106. a glaze trough; 107. a bearing A; 108. an annular groove A; 109. a ball A; 2. a drive mechanism; 201. a motor A; 202. a rotating shaft A; 203. a circular block; 204. a circular limiting block; 205. an arc-shaped slot; 206. shifting the column; 3. a transmission mechanism; 301. a circular drive plate; 302. a cylinder A; 303. a bearing B; 304. a distribution box; 305. a grooved wheel; 306. a U-shaped toggle groove; 307. a limiting arc-shaped groove; 308. an annular arc chute A; 309. a support column B; 3010. a ring block B; 3011. a support pillar C; 3012. an annular groove B; 3013. an annular inner rack; 3014. a ball B; 3015. an annular arc chute B; 4. a transmission auxiliary mechanism; 401. a circular plate; 402. a bearing C; 403. a bearing D; 404. a rotating shaft B; 405. a motor B; 406. a cylinder B; 407. a bearing E; 408. a transmission gear; 409. a driving gear; 5. a carrying mechanism; 501. a load-bearing disc; 502. a circular protrusion; 503. a rotating shaft B; 504. a driven gear; 505. a rubber layer;

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 22:

the invention provides a bowl opening glaze sealing mechanism based on ceramic production, which comprises: a driving mechanism 2 is arranged on the left side of the supporting table 1, and a transmission mechanism 3 which is in transmission fit with the driving mechanism 2 is arranged in the center of the top end of the supporting table 1; the supporting table 1 comprises a circular bottom plate 101, supporting legs 102, supporting columns A103, an annular block A104, extending blocks 105, a glaze groove 106, bearings A107, an annular groove A108 and balls A109, wherein the bottom end surface of the circular bottom plate 101 is fixedly connected with the four supporting legs 102 in an annular array shape, the annular block A104 in a coaxial line state with the circular bottom plate 101 is arranged above the circular bottom plate 101, the bottom end surface of the annular block A104 is fixedly connected with the top end surface of the circular bottom plate 101 through six supporting columns A103 distributed in an annular array shape, the right side in front of the annular block A104 is provided with one extending block 105, the top end surface of the extending block 105 is provided with one glaze groove 106, the left side of the top end surface of the circular bottom plate 101 is internally embedded with one bearing A107, the inner peripheral surface of the annular block A104 is provided with one annular groove A108, and the top surfaces and the bottom surfaces of the inner ends of; the top end of the transmission mechanism 3 is provided with a transmission auxiliary mechanism 4 which is coaxial with the transmission mechanism, and the transmission auxiliary mechanism 4 is engaged and matched with the transmission mechanism 3 in a transmission way; the transmission mechanism 3 comprises a circular transmission plate 301, a cylinder A302, a bearing B303, a distribution box 304, a grooved pulley 305, a U-shaped toggle groove 306, a limit arc-shaped groove 307, an annular arc-shaped sliding groove A308, a support column B309, an annular block B3010, a support column C3011, an annular groove B3012, an annular inner rack 3013, a ball B3014 and an annular arc-shaped sliding groove B3015, wherein the axle center part of the bottom end surface of the circular transmission plate 301 is fixedly connected with a cylinder A302, the bottom end surface of the cylinder A302 is fixedly connected with a grooved pulley 305 which is coaxial with the cylinder A302, the periphery of the grooved pulley 305 is in an annular array shape and is provided with six U-shaped toggle grooves 306 and six limit arc-shaped grooves 307, the six U-shaped toggle grooves 306 and the six limit arc-shaped grooves 307 are distributed at intervals, the right side of the top end surface of the circular transmission plate 301 is embedded with the bearing B303, the distribution box 304 is arranged on the right side of the bottom end surface of the circular transmission plate 301, an annular block B3010 coaxial with the circular transmission plate 301 is arranged right above the circular transmission plate 301, the bottom end face of the annular block B3010 is fixedly connected with the top end face of the circular transmission plate 301 through six support pillars B309 distributed in an annular array form, an annular groove B3012 is formed in the inner peripheral surface of the annular block B3010, annular arc-shaped chutes B3015 are formed in the top and bottom faces of the inner end of the annular groove B3012, an annular inner rack 3013 is arranged in the annular groove B3012, a plurality of balls B3014 are embedded and rotatably mounted on the bottom end face and the top end face of the annular inner rack 3013 in an annular array form, the balls B3014 embedded and rotatably mounted on the bottom end face and the top end face of the annular inner rack 3013 are respectively and slidably connected in the annular arc-shaped chutes B3015, six support pillars C3011 are fixedly connected to the top end face of the annular block B3010 in an annular array form, the circular transmission plate 301 is located in the annular groove A108 in the installation, the outer end face of the circular transmission plate 301 is not contacted with the inner end face of the annular groove A108, the ball A109 is connected in the annular arc-shaped sliding groove A308 in a sliding manner, the limiting arc-shaped groove 307 is connected in the circular limiting block 204 in a tangential sliding manner, and the toggle column 206 is in transmission fit with the U-shaped toggle groove 306; six groups of bearing mechanisms 5 are arranged on the top end surface of the transmission auxiliary mechanism 4 in an annular array shape, and the bearing mechanisms 5 are engaged with the transmission mechanism 3 in a transmission fit; the bearing mechanism 5 comprises a bearing disc 501, a circular protrusion 502, a rotating shaft B503, a driven gear 504 and a rubber layer 505, wherein the shaft center part of the bottom end face of the bearing disc 501 is provided with the circular protrusion 502, the shaft center part of the bottom end face of the circular protrusion 502 is fixedly connected with the rotating shaft B503, the bottom end of the rotating shaft B503 is fixedly connected with the driven gear 504, the rubber layer 505 is adhered to the top end face of the bearing disc 501, the circular protrusion 502 is fixedly connected with a bearing C402 in the installation state of the bearing mechanism 5, and the driven gear 504 is meshed with an annular inner rack 3013.

Wherein, actuating mechanism 2 is including motor A201, pivot A202, circular block 203, circular stopper 204, arc-shaped groove 205, stir post 206, pivot A202 bottom is connected with motor A201 stationary phase, motor A201 top fixedly connected with one rather than the circular block 203 with the axle center, and circular block 203 top end face axle center position fixedly connected with one circular stopper 204, an arc-shaped groove 205 has been seted up to circular stopper 204 outer peripheral face, and circular block 203 top end face stirs post 206 for arc-shaped groove 205 position fixedly connected with, under actuating mechanism 2 installation status, pivot A202 is connected with bearing A107 fixedly, motor A201 fixed connection is on circular bottom plate 101 bottom face.

Wherein, the transmission auxiliary mechanism 4 comprises a circular plate 401, a bearing C402, a bearing D403, a rotating shaft B404, a motor B405, a cylinder B406, a bearing E407, a transmission gear 408 and a driving gear 409, the top end of the circular plate 401 is in an annular array shape and is provided with six bearings C402 in an embedded manner, the right side of the top end surface of the circular plate 401 is provided with the bearing D403 in an embedded manner, the bearing D403 is internally and fixedly connected with the rotating shaft B404, the top end surface of the rotating shaft B404 and the top end surface of the circular plate 401 are positioned at the same horizontal plane, the bottom end of the rotating shaft B404 is fixedly connected with the motor B405, the rotating shaft B404 is fixedly connected with the driving gear 409, the bottom end surface of the circular plate 401 is positioned at the right side of the bearing D403 and is fixedly connected with the cylinder B406, the bottom end of the cylinder B406 is fixedly connected with the transmission gear, when the transmission auxiliary mechanism 4 is installed, the bottom end face of the circular plate 401 is fixedly connected with the top end face of the support column C3011, the rotating shaft B404 is fixedly connected with the bearing B303, the motor B405 is fixedly connected with the bottom end face of the circular transmission plate 301, the motor B405 is electrically connected with the distribution box 304, and the transmission gear 408 is meshed with the annular inner rack 3013.

When in use:

firstly, a worker at the front side of a support table 1 adds glaze into a glaze trough 106, another worker at the rear side of the support table 1 can sequentially place six ceramic bowls to be glazed at the bowl openings on bearing discs 501 in six groups of bearing mechanisms 5 respectively, a rubber layer 505 is bonded on the top end surface of each bearing disc 501, and the rubber layer 505 is arranged to facilitate the subsequent bearing mechanisms 5 to drive the ceramic bowls to rotate at a constant speed, so that frictional resistance is achieved, and the ceramic bowls are prevented from being separated from the bearing discs 501 during rotation;

step two, a motor B405 starts a driving rotating shaft B404 to drive a driving gear 409 to rotate, so that a transmission gear 408 meshed with the driving gear is driven to synchronously rotate, and the transmission gear 408 is meshed with an annular inner rack 3013, so that the transmission gear 408 is meshed with a transmission annular inner rack 3013 to rotate along an annular groove B3012 through sliding fit of a ball B3014 and an annular arc-shaped chute B3015, so that driven gears 504 in six groups of bearing mechanisms 5 meshed with the annular inner rack 3013 are driven to synchronously rotate, the six groups of bearing mechanisms 5 respectively rotate along a bearing C402, rotation of ceramic bowls is realized, workers at the front side of a support platform 1 can conveniently contact ceramic bowl openings in a rotating state through a glaze staining tool, and glaze sealing operation of the ceramic bowl openings is finished;

step three, the motor A201 starts the driving rotating shaft A202 to drive the circular block 203 to rotate, firstly, the circular limit block 204 slides in the limit arc-shaped groove 307 in a tangent manner, the limit transmission mechanism 3 ensures that the position is inconvenient, when the toggle column 206 slides into the U-shaped toggle groove 306, the toggle grooved wheel 305 rotates, so that the circular transmission plate 301 rotates along the annular groove A108 through the sliding fit of the annular arc-shaped sliding groove A308 and the ball A109, and simultaneously drives the transmission auxiliary mechanism 4 fixedly connected with the limit transmission mechanism 3 to rotate, thereby driving the six groups of bearing mechanisms 5 fixedly arranged on the transmission auxiliary mechanism 4 to rotate together, when the circular block 203 rotates for one circle, the limit transmission mechanism 3 rotates for sixty degrees, thereby driving the six groups of bearing mechanisms 5 fixedly arranged on the transmission auxiliary mechanism 4 to feed for one bit, and simultaneously, the toggle column 206 separates from the U-shaped toggle groove 306, the circular limit block 204 slides in the other limit arc-shaped groove 307, thereby spacing drive mechanism 3 guarantees its position inconvenience once more, be convenient for the staff at this time interval to the transmission to a set of ceramic bowl of putting on bearing mechanism 5 of brace table 1 front side carry out bowl mouth and seal the glaze operation, and when stirring post 206 and slide into another department U-shaped once more and stir the groove 306 in, repeat above-mentioned operation once more, make six groups of bearing mechanism 5 of fixed mounting on transmission auxiliary mechanism 4 feed one bit once more, realize ceramic bowl's intermittent type formula and feed, the staff that both is located brace table 1 front side of having been convenient for seals the glaze operation to ceramic bowl, the staff that is located brace table 1 rear side of also being convenient for realizes accomplishing bowl mouth and seals the glaze ceramic bowl and treats the mutual change of bowl mouth and seal the glaze ceramic bowl.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (5)

1. The utility model provides a bowl mouth seals glaze mechanism based on ceramic manufacture which characterized in that: the device comprises a supporting table (1), wherein a driving mechanism (2) is arranged on the left side of the supporting table (1), and a transmission mechanism (3) in transmission fit with the driving mechanism (2) is arranged in the center of the top end of the supporting table (1); the supporting table (1) comprises a circular bottom plate (101), supporting legs (102), supporting columns A (103), a ring-shaped block A (104), extending blocks (105), a glaze groove (106), bearings A (107), an annular groove A (108) and balls A (109), wherein the bottom end of the circular bottom plate (101) is in an annular array shape and is fixedly connected with four supporting legs (102), the ring-shaped block A (104) in a coaxial line state with the circular bottom plate (101) is arranged above the circular bottom plate (101), the bottom end face of the ring-shaped block A (104) is fixedly connected with the top end face of the circular bottom plate (101) through six supporting columns A (103) distributed in an annular array shape, the extending block (105) is arranged on the right side in front of the ring-shaped block A (104), the glaze groove (106) is formed in the top end face of the extending block (105), one bearing A (107) is embedded in the left side of the top, an annular groove A (108) is formed in the inner circumferential surface of the annular block A (104), and a plurality of balls A (109) are respectively embedded and rotatably mounted in the annular array shape on the top surface and the bottom surface of the inner end of the annular groove A (108); the top end of the transmission mechanism (3) is provided with a transmission auxiliary mechanism (4) which is coaxial with the transmission mechanism, and the transmission auxiliary mechanism (4) is meshed with the transmission mechanism (3) for transmission fit; six groups of bearing mechanisms (5) are installed on the top end surface of the transmission auxiliary mechanism (4) in an annular array shape, and the bearing mechanisms (5) are engaged and matched with the transmission mechanism (3) in a transmission manner.

2. The bowl opening glaze sealing mechanism based on ceramic production as claimed in claim 1, wherein: the driving mechanism (2) comprises a motor A (201), a rotating shaft A (202), a circular block (203), a circular limiting block (204), an arc-shaped groove (205) and a toggle column (206), the bottom end of the rotating shaft A (202) is fixedly connected with a motor A (201), the top end of the motor A (201) is fixedly connected with a circular block (203) which is coaxial with the motor A, and the axle center part of the top end surface of the circular block (203) is fixedly connected with a circular limiting block (204), the outer peripheral surface of the round limiting block (204) is provided with an arc-shaped groove (205), and the top end surface of the circular block (203) is fixedly connected with a toggle column (206) relative to the arc-shaped groove (205), in the installation state of the driving mechanism (2), the rotating shaft A (202) is fixedly connected with the bearing A (107), the motor A (201) is fixedly connected to the bottom end face of the circular bottom plate (101).

3. The bowl opening glaze sealing mechanism based on ceramic production as claimed in claim 1, wherein: the transmission mechanism (3) comprises a circular transmission plate (301), a cylinder A (302), a bearing B (303), a distribution box (304), a grooved pulley (305), a U-shaped toggle groove (306), a limiting arc-shaped groove (307), an annular arc-shaped sliding groove A (308), a supporting column B (309), an annular block B (3010), a supporting column C (3011), an annular groove B (3012), an annular inner rack (3013), a ball B (3014) and an annular arc-shaped sliding groove B (3015), wherein the axis part of the bottom end surface of the circular transmission plate (301) is fixedly connected with the cylinder A (302), the bottom end surface of the cylinder A (302) is fixedly connected with the grooved pulley (305) which has the same axis with the cylinder A, the outer peripheral surface of the grooved pulley (305) is in an annular array shape and is provided with six U-shaped toggle grooves (306) and six limiting arc-shaped grooves (307), and the six U-shaped toggle grooves (306) and the six limiting arc-shaped slots, a bearing B (303) is embedded in the right side of the top end face of the circular transmission plate (301), a distribution box (304) is installed on the right side of the bottom end face of the circular transmission plate (301), annular arc sliding chutes A (308) are formed in adjacent edge portions of the top end face and the bottom end face of the circular transmission plate (301), an annular block B (3010) coaxial with the circular transmission plate is arranged over the circular transmission plate (301), the bottom end face of the annular block B (3010) is fixedly connected with the top end face of the circular transmission plate (301) through six support columns B (309) distributed in an annular array shape, an annular groove B (3012) is formed in the inner peripheral surface of the annular block B (3010), annular arc sliding chutes B (3015) are formed in the top face and the bottom face of the inner end of the annular groove B (3012), an annular inner rack (3013) is arranged in the annular groove B (3012), and the bottom end surface and the top end surface of the annular inner rack (3013) are both in an annular array shape and are embedded with a plurality of balls B (3014) in a rotating way, and balls B (3014) embedded and rotatably installed on the bottom end surface and the top end surface of the annular inner rack (3013) are respectively connected in the two annular arc-shaped chutes B (3015) in a sliding way, the top end surface of the annular block B (3010) is in an annular array shape and is fixedly connected with six support columns C (3011), when the transmission mechanism (3) is in an installation state, the circular transmission plate (301) is positioned in the annular groove A (108), the outer end surface of the circular driving plate (301) is not contacted with the inner end surface of the annular groove A (108), the ball A (109) is connected in the annular arc chute A (308) in a sliding way, the limiting arc-shaped groove (307) is in tangential sliding connection with the inside of the circular limiting block (204), and the toggle column (206) is in transmission fit with the U-shaped toggle groove (306).

4. The bowl opening glaze sealing mechanism based on ceramic production as claimed in claim 1, wherein: the transmission auxiliary mechanism (4) comprises a circular plate (401), a bearing C (402), a bearing D (403), a rotating shaft B (404), a motor B (405), a cylinder B (406), a bearing E (407), a transmission gear (408) and a driving gear (409), wherein the top end surface of the circular plate (401) is in an annular array shape, six bearings C (402) are embedded and installed, the bearing D (403) is embedded and installed in the right side of the top end surface of the circular plate (401), the rotating shaft B (404) is fixedly connected in the bearing D (403), the top end surface of the rotating shaft B (404) and the top end surface of the circular plate (401) are located on the same horizontal plane, the bottom end of the rotating shaft B (404) is fixedly connected with the motor B (405), the driving gear (409) is fixedly connected to the rotating shaft B (404), and the bottom end surface of the circular plate (401) is located at the right side of the bearing D (403) and, and the bottom end of the cylinder B (406) is fixedly connected with a transmission gear (408) through a bearing E (407), the transmission gear (408) and the driving gear (409) are positioned at the same horizontal position, the transmission gear (408) is meshed with the driving gear (409), the bottom end face of the circular plate (401) is fixedly connected with the top end face of the support column C (3011) in the installation state of the transmission auxiliary mechanism (4), the rotating shaft B (404) is fixedly connected with the bearing B (303), the motor B (405) is fixedly connected with the bottom end face of the circular transmission plate (301), the motor B (405) is electrically connected with the distribution box (304), and the transmission gear (408) is meshed with the annular inner rack (3013).

5. The bowl opening glaze sealing mechanism based on ceramic production as claimed in claim 1, wherein: bearing mechanism (5) is including bearing disc (501), circular arch (502), pivot B (503), driven gear (504), rubber layer (505), bearing disc (501) bottom end face axle center part is provided with a circular arch (502), and circular arch (502) bottom end face axle center part fixedly connected with pivot B (503), pivot B (503) bottom fixedly connected with driven gear (504), bearing disc (501) top end face bonds there is one deck rubber layer (505), under bearing mechanism (5) installation state, circular arch (502) are connected with bearing C (402) is fixed, driven gear (504) mesh with annular inner rack (3013).

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