CN220362739U - Rotary structure of ceramic continuous grouting molding equipment - Google Patents

Abstract

The utility model discloses a rotary structure of ceramic continuous grouting forming equipment, wherein a rotary driving mechanism is arranged below a grouting mechanism, when a to-be-grouting die moves to a grouting station along with a die placing frame, the corresponding rotary driving mechanism is arranged below the die placing frame, after a die pressing mechanism is opened and the restriction on the die is released, the rotary driving mechanism ascends to enable a power output end to be combined with a power input end, a rotating shaft drives a tray and the die on the tray to rotate, and the grouting mechanism performs grouting at the same time, so that centrifugal grouting is completed by rotating the grouting mechanism and the die; under the premise of realizing centrifugal grouting, a design of separable driving is adopted, a rotary driving mechanism with larger volume and weight is independently arranged on a frame or the ground, interference with a mold placing frame is avoided, the large increase of energy consumption caused by rotation is avoided, the design scheme is more excellent, the defects that ceramic products generate clay deformation and the like are effectively reduced, and the manufacturing quality of the ceramic products is improved under the condition of lower energy consumption increase.

Description

Rotary structure of ceramic continuous grouting molding equipment

Technical Field

The utility model belongs to the technical field of inorganic nonmetallic material component molding, and particularly relates to a rotary structure of ceramic continuous grouting molding equipment.

Background

Ceramic slip casting is an important process in the ceramic production process, and is to inject slurry for manufacturing ceramic products into corresponding molds, so that the slurry is dispersedly adsorbed on the molds to form blank slurry layers with the same shape as the molds, and the blank slurry layers are gradually thickened along with the extension of time, and when the blank slurry layers reach a certain thickness, the blank slurry layers are separated from the molds through drying shrinkage. In the past, ceramic grouting is generally accomplished by manual work or semi-automatic slip casting machine, and grouting, reverse slurry upset and stoving are gone on respectively to adopt independent equipment respectively in most, and each process dispersedly goes on, and the mould that pours into has mud flows between each process corresponding station or equipment, not only leads to production efficiency lower, and the cost of labor is high, and product quality stability is poor.

Along with the development of automation, in order to improve the working efficiency and quality of ceramic production, at present, most ceramic production enterprises begin to adopt automatic grouting forming equipment integrating grouting, reverse grouting overturning and drying, and applicant adopts grouting forming equipment similar to that disclosed in chinese patent CN113442278A for ceramic production, except that the automatic grouting forming equipment adopted by applicant at present is provided with a plurality of mold placing frames arranged at intervals along a circulation path, and the plurality of mold placing frames are circularly moved by means of a chain type transmission structure, so that the mold placing frames sequentially reach stations for performing mold installation, grouting, reverse grouting overturning, drying, demolding and blank taking. In the past, when grouting is carried out by a manual or semi-automatic grouting machine, the mould is generally in a rotating state to realize centrifugal grouting, so that slurry is abutted against the outer wall of the mould under the action of centrifugal force to form a compact porcelain blank, in addition, bubbles in the slurry are concentrated on the inner side when the mould rotates due to lighter weight, and finally are broken and discharged, thereby reducing the phenomena of bubbles, deformation and mud strands and improving the quality of the porcelain blank; however, in the automatic grouting molding device, in order to avoid the falling of the mold in the process of moving along with the mold placing frame and reversing the slurry, the mold is generally fixed on the mold placing frame by vertical pressing through a mold pressing mechanism capable of opening and closing, and the mold is static during grouting and can not realize centrifugal grouting, so that the production efficiency is improved, but the quality of the porcelain blank is not high.

Compared with the grouting forming equipment for ceramic production disclosed in the Chinese patent CN113442278A, the grouting forming equipment has the advantages that a die rotating unit is added on a die placing frame, a die pressing mechanism can be opened during grouting, and the die rotating unit drives a die to rotate to realize centrifugal grouting, but the die rotating unit is integrally integrated below the die placing frame and cannot be separated, so that the volume and the weight of the die placing frame are greatly increased, and particularly, the volume and the weight of a transmission mechanism and a power source are larger; if the improvement is directly applied to the automatic slip casting equipment currently adopted by the applicant, the interference with the circulating movement of each mold rack is likely to occur, and the energy consumption of the circulating movement of each mold rack is greatly increased.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide a rotary structure of ceramic continuous grouting forming equipment, solve the technical problem that the existing automatic grouting forming equipment is poor in applicability of modification of centrifugal grouting, and achieve the effects of better modification scheme and improvement of manufacturing quality of porcelain under the condition of lower energy consumption increase.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the rotary structure of the ceramic continuous grouting molding equipment comprises a die placing rack for placing dies, wherein the die placing rack is provided with a die pressing mechanism which can vertically press the dies and can be opened and closed; a tray is arranged below the die pressing mechanism on the die placing frame and used for holding the die, a vertically arranged rotating shaft is synchronously connected below the tray in a rotating way, and the rotating shaft is connected with the die placing frame in a rotating way;

the lower extreme of pivot extends and runs through to the below of mould rack and have the power input, and the below of mould rack is equipped with the rotary driving mechanism that can vertically go up and down, rotary driving mechanism's power take off end with the power input matches, and rotary driving mechanism rises and descends and can realize respectively that the combination of transmission between power take off end and the power input is separated.

Further, a cylindrical connecting sleeve vertically penetrates through the die placing frame, the connecting sleeve is fixedly connected with the die placing frame, the rotating shaft penetrates through the connecting sleeve, and the connecting sleeve is rotatably connected with the rotating shaft through a bearing and supports the rotating shaft.

Further, one end of the connecting sleeve above the die placing frame is provided with a bulge along the circumferential direction, the bulge forms a circle of supporting part, the lower surface of the supporting part is abutted to the upper surface of the die placing frame, and the supporting part is fixedly connected with the die placing frame through a vertically penetrating bolt.

Further, the upper end of the rotating shaft is fixedly connected with the tray, the lower end of the rotating shaft is connected with a transmission head, and the lower end surface of the transmission head is provided with a circle of tooth parts and is used as the power input end; the rotary driving mechanism comprises a power output shaft which is vertically arranged, the upper end of the power output shaft is connected with a face gear which is used as the power output end, and the face gear and the transmission head are vertically opposite and can be meshed with the circle of tooth parts;

or the transmission head connected with the lower end of the rotating shaft and the power output shaft of the rotary driving mechanism adopt non-gear transmission, such as friction transmission, shifting fork transmission, planar friction wheel friction transmission, synchronous belt tooth meshing transmission and the like.

Further, the face gear is a bevel gear, the lower end face of the transmission head is a conical surface which is concave inwards, and the circle of tooth parts are positioned on the conical surface and can be meshed with the bevel gear;

or the concave friction wheel and the convex friction wheel are in friction engagement transmission, or the transmission shaft is provided with a horizontal expenditure shifting fork which is in engagement transmission with a vertical expenditure shifting fork plug on the other transmission shaft, the plane friction wheel is in friction transmission, the synchronous belt is in gear engagement transmission, and the like.

Further, the rotary driving mechanism comprises a mounting frame which is arranged below the die placing frame in parallel, a rotary power source is arranged on the mounting frame, the lower end of the power output shaft is connected with the rotary power source in a transmission manner, a lifting power source is vertically arranged below the mounting frame, and the telescopic end of the lifting power source is fixedly connected with the mounting frame so as to drive the mounting frame to lift.

Further, the rotary power source is a motor, a rotary cylinder or a rotary hydraulic cylinder, and the lifting power source is a cylinder or a hydraulic driving cylinder.

Further, the power output shaft is a flexible spring shaft, and can also be other rigid or flexible shafts.

Compared with the prior art, the utility model has the following beneficial effects:

the rotary structure of the ceramic continuous grouting forming equipment is applied to the continuous automatic grouting forming equipment currently adopted by the applicant in the background technology, a rotary driving mechanism is arranged under a grouting mechanism, when a to-be-grouting die moves to a grouting station along with a die placing frame, the rotary driving mechanism is correspondingly arranged under the die placing frame, after a die pressing mechanism is opened and the restriction on the die is relieved, the rotary driving mechanism is lifted to enable a power output end to be in transmission combination with a power input end, and a rotating shaft drives a tray and the die to rotate, so that centrifugal grouting is completed by being matched with the grouting mechanism; according to the utility model, on the premise of realizing centrifugal grouting, a design of rotation and separable driving is adopted, a tray for placing a die and enabling the die to rotate is only arranged on a die placing frame, and a rotating shaft for enabling the tray to be in rotating connection with the die placing frame and inputting power is arranged, a rotary driving mechanism with larger volume and weight is independently arranged on a frame or the ground, interference between the rotary driving mechanism and the movement of the die placing frame and reverse grouting overturning is avoided, and the large increase of energy consumption caused by the addition of a rotary function is avoided, so that the problem that how to realize low-energy-consumption and noninterference centrifugal grouting of the conventional continuous grouting forming equipment is effectively solved.

Drawings

FIG. 1 is a front view showing a rotary structure of a ceramic continuous slip casting apparatus of an embodiment;

FIG. 2 is an enlarged schematic view of FIG. 1 at A;

the device comprises a die 1, a die placing frame 2, a die pressing mechanism 3, a tray 4, a rotating shaft 5, a frame 6, a grouting mechanism 7, a connecting sleeve 8, a bearing 9, a supporting part 10, a transmission head 11, a circle of tooth part 12, a power output shaft 13, a face gear 14, a mounting frame 15, a rotating power source 16 and a lifting power source 17.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to fall within the scope of the utility model.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. In the description of the present utility model, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships conventionally put in use of the inventive product, are merely for convenience of describing the present utility model and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance. Furthermore, the terms "horizontal," "vertical," and the like do not denote a requirement that the component be absolutely horizontal or overhang, but rather may be slightly inclined. As "horizontal" merely means that its direction is more horizontal than "vertical", and does not mean that the structure must be perfectly horizontal, but may be slightly inclined. In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in a specific case by those skilled in the art.

Examples:

referring to fig. 1, a rotary structure of a ceramic continuous grouting forming device includes a mold placing frame 2 for placing a mold 1, wherein the mold placing frame 2 is provided with a mold pressing mechanism 3 capable of vertically pressing the mold 1 on the mold placing frame 2 and opening and closing; a tray 4 is arranged below the die pressing mechanism 3 on the die placing frame 2 and used for holding the die 1, a vertically arranged rotating shaft 5 is fixedly connected below the tray 4, and the rotating shaft 5 is rotationally connected with the die placing frame 2; the lower extreme of pivot 5 extends to the below of mould rack 2 and has the power input, and the below of mould rack 2 is equipped with the rotary driving mechanism that can vertically go up and down, rotary driving mechanism's power take off end with the power input matches, and rotary driving mechanism rises and descends and can realize respectively that the transmission combines and separates between power take off end and the power input.

The rotary structure adopts a design with separable rotation and drive, a tray 4 for placing the die 1 and enabling the die to rotate and a rotating shaft 5 for enabling the tray 4 to be in rotary connection with the die placing frame 2 and inputting power are arranged on the die placing frame 2, and a rotary driving mechanism for driving the tray 4 through the driving rotating shaft 5 is arranged below the die placing frame 2 and realizes combination and separation of transmission through lifting; in practice, the rotary driving mechanism can be installed on the frame 6 or the ground of the slip casting device, and for the slip casting device for ceramic production disclosed in Chinese patent CN113442278A, the rotary driving mechanism is arranged right below the die placing frame 2; for the grouting forming equipment currently adopted by the applicant in the background technology, a rotary driving mechanism is arranged right below the grouting mechanism 7; when the mould placing frame 2 on which the mould 1 is to be injected moves to the injection station, the mould placing frame 2 is positioned right above the rotary driving mechanism, the mould pressing mechanism 3 is controlled to be opened to release the limitation on the mould 1, namely the mould 1 is not pressed and fixed on the tray 4 any more, the mould 1 can rotate along with the tray 4, at the moment, the rotary driving mechanism rises to enable the power output end to be in transmission combination with the power input end, the tray 4 and the mould 1 on the power output end are driven to rotate through the rotating shaft 5, so that the centrifugal injection is completed by being matched with the injection mechanism 7, after the centrifugal injection is completed, the rotary driving mechanism descends to enable the power output end to be separated from the power input end, and meanwhile, the mould pressing mechanism 3 is closed again to press and fix the mould, so as to avoid the follow-up mould from falling in the process of moving along with the mould placing frame and reversing the mould; in addition, the rotational speed at the time of centrifugal grouting is low, generally below 100r/min, and the rotational speed should be reduced appropriately for large-sized blanks, so that even if the mold 1 is not fixedly connected with the tray 4, the mold 1 does not fall off the tray 4 during rotation, and as shown in fig. 2, in this embodiment, a concave surface matched with the bottom of the mold 1 is also machined on the upper surface of the tray 4, so that even if the mold pressing mechanism 3 is opened, the mold 1 is difficult to slip on the tray 4, and the possibility that the mold 1 falls off the tray 4 during centrifugal grouting is further reduced.

According to the rotary grouting structure, on the premise of realizing centrifugal grouting, a separable transmission design is adopted, a driving mechanism with larger volume and weight is independently arranged on a frame 6 or the ground, interference caused by movement of a die placing frame 2 and inversion and slurry overturning is avoided, and the large increase of energy consumption caused by the addition of a rotary function is avoided, so that the problem that how to realize low-energy-consumption and interference-free centrifugal grouting of the conventional continuous grouting forming equipment is effectively solved.

Referring to fig. 1 and 2, a cylindrical connecting sleeve 8 is vertically and penetratingly arranged on a die placing frame 2, the connecting sleeve 8 is fixedly connected with the die placing frame 2, a rotating shaft 5 penetrates through the connecting sleeve 8, and the connecting sleeve 8 is rotatably connected with the rotating shaft 5 through a bearing 9 and supports the rotating shaft 5; as shown in fig. 1, in the grouting equipment currently adopted by the applicant, the bottom plate of the mold rack 2 is composed of two parallel steel pipes arranged at intervals, and the purpose of the grouting equipment is to reduce the weight of the mold rack 2; in order to improve the rotary structure based on the above, as shown in fig. 1 and 2, in the embodiment, a connecting sleeve 8 is fixedly arranged between two steel pipes, a reaming is processed on the inner wall of the connecting sleeve 8 for installing a bearing 9, a shaft shoulder is correspondingly processed on a rotating shaft 5, the lower surface of an outer ring of the bearing 9 is abutted with a step surface formed by the reaming, and the upper surface of an inner ring of the bearing 9 is abutted with the shaft shoulder, so that the rotating shaft 5 passes through the connecting sleeve 8 and realizes rotary connection and supporting effect through the bearing 9; the arrangement of the connecting sleeve 8 is simpler and easier to implement than the modification of the entire mould holder 2.

Referring to fig. 1 and 2, in this embodiment, in order to realize the fixed connection between the connecting sleeve 8 and the mold placing frame 2, the following structure is adopted: one end of the connecting sleeve 8 above the die placing frame 2 is formed with a circle of supporting parts 10 in a protruding mode along the circumferential direction, the lower surfaces of the supporting parts 10 are in butt joint with the upper surface of the die placing frame 2, and the supporting parts 10 are fixedly connected with the die placing frame 2 through bolts (not shown in the figure) penetrating vertically.

Referring to fig. 1 and 2, in this embodiment, in order to realize the ascending and descending of the above-mentioned rotation driving mechanism, the power output end and the power input end can be respectively combined and separated, and the specific structures adopted by the power input end and the rotation driving mechanism are as follows:

the upper end of the rotating shaft 5 is fixedly connected with the tray 4, the lower end of the rotating shaft 5 is connected with a transmission head 11, and the lower end surface of the transmission head 11 is provided with a circle of tooth parts 12 and is used as the power input end; the rotary driving mechanism comprises a power output shaft 13 which is vertically arranged, the upper end of the power output shaft 13 is connected with a face gear 14, the face gear 14 is used as the power output end, and the face gear 14 and the transmission head 11 are vertically opposite and can be meshed with the circle of tooth parts 12; in this embodiment, the face gear 14 is a bevel gear, the lower end surface of the driving head 11 is a conical surface recessed inwards, and the ring of teeth 12 is located on the conical surface and can be meshed with the bevel gear;

the rotary driving mechanism comprises a mounting frame 15 which is arranged below the die placing frame 2 in parallel, a rotary power source 16 is arranged on the mounting frame 15, the lower end of the power output shaft 13 is in transmission connection with the rotary power source 16, a lifting power source 17 is vertically arranged below the mounting frame 15, and the telescopic end of the lifting power source 17 is fixedly connected with the mounting frame so as to drive the mounting frame 15 to lift; in this embodiment, the rotary power source 16 is a motor, a rotary cylinder or a rotary hydraulic cylinder, and the lifting power source 17 is a cylinder or a hydraulic driving cylinder;

thus, when the mould 1 on the mould rack 2 is to be injected, the mould pressing mechanism 3 is opened, the restriction on the mould 1 is removed, the lifting power source 17 drives the mounting frame 15 to lift, the bevel tooth surface of the face gear 14 is meshed with the circle of tooth part 12 on the lower end surface of the transmission head 11, the motor 16 is started, the output shaft of the motor 16 rotates and drives the tray 4 to rotate sequentially through the power output shaft 13, the bevel gear 14, the transmission head 11 and the rotating shaft 5, and the mould 1 rotates along with the tray 4, so that the centrifugal grouting is completed by matching with the grouting mechanism 7.

Referring to fig. 2, in this embodiment, the power output shaft 13 is a flexible spring shaft; the spring with smaller pitch is used as a flexible spring shaft, so that the power output shaft 13 has certain flexibility in the transverse direction while ensuring the effective transmission, and the situation that the transmission cannot be meshed due to the fact that the bevel tooth surface of the face gear 14 and the circle of tooth parts 12 are not completely right opposite can be avoided; when the bevel gear surface of the face gear 14 and the circle of tooth parts 12 are slightly misplaced, the bevel gear surface and the cone surfaces of the circle of tooth parts 12 are inclined surfaces, so that the effects of guiding and rectifying the meshing of the bevel gear surface and the circle of tooth parts are achieved, after the face gear 14 is contacted with the circle of tooth parts 12 along with the action of the cylinder 17, the bevel gear surface of the face gear 14 gradually falls into the concave cone surfaces and is meshed with the circle of tooth parts 12, and the power output shaft 13 has certain deformation in the transverse direction but does not influence the transmission, so that the requirement on the installation precision can be reduced, and the running stability is improved.

In practice, it will be understood that the trays 4 and the rotating shafts 5 on the mold placing frame 2 are multiple sets of face gears 14 (power output ends) arranged at intervals along the length direction of the trays and the rotating shafts, and the face gears 14 are corresponding to the trays and the rotating shafts, and the multiple sets of face gears 14 can be driven by one-to-one motors 16 as shown in the embodiment drawings, or the multiple sets of face gears 14 can be synchronously driven by one total driving source through a transmission mechanism, which is not particularly limited.

In the implementation process, if the mold 1 is expected to rotate along with the tray 4 and still keep the function of the mold pressing mechanism in the process of realizing centrifugal grouting, a plane bearing or a thrust bearing can be additionally arranged; specifically, a plane bearing is arranged between a pressing arm of the die pressing mechanism acting on the upper surface of the die and the upper surface of the die 1, the inner ring of the plane bearing is sleeved on the outer side of a grouting port on the upper surface of the die 1, grouting is not affected, and when the die 1 rotates along with the tray 4, the pressing arm can keep and transmit the pressure for pressing the die 1 on the tray 4 through the plane bearing; for ease of implementation, the planar bearing is preferably fixed directly to the hold-down arm.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the technical solution, and those skilled in the art should understand that modifications and equivalents may be made to the technical solution of the present utility model without departing from the spirit and scope of the present utility model, and all such modifications and equivalents are included in the scope of the claims.

Claims (8)

1. The rotary structure of the ceramic continuous grouting molding equipment comprises a die placing rack for placing dies, wherein the die placing rack is provided with a die pressing mechanism which can vertically press the dies and can be opened and closed; the method is characterized in that: a tray is arranged below the die pressing mechanism on the die placing frame and used for holding the die, a vertically arranged rotating shaft is synchronously connected below the tray in a rotating way, and the rotating shaft is connected with the die placing frame in a rotating way;

the lower extreme of pivot extends and runs through to the below of mould rack and have the power input, and the below of mould rack is equipped with the rotary driving mechanism that can vertically go up and down, rotary driving mechanism's power take off end with the power input matches, and rotary driving mechanism rises and descends and can realize respectively that the combination of transmission between power take off end and the power input is separated.

2. The rotary structure of a ceramic continuous slip casting apparatus according to claim 1, wherein: the mould rack is vertically penetrated and provided with a cylindrical connecting sleeve, the connecting sleeve is fixedly connected with the mould rack, the rotating shaft penetrates through the connecting sleeve, and the connecting sleeve is rotationally connected with the rotating shaft through a bearing and supports the rotating shaft.

3. The rotary structure of a ceramic continuous slip casting apparatus according to claim 2, wherein: one end of the connecting sleeve, which is positioned above the die placing frame, is provided with a bulge along the circumferential direction, the bulge forms a circle of supporting part, the lower surface of the supporting part is abutted with the upper surface of the die placing frame, and the supporting part is fixedly connected with the die placing frame through a vertically penetrating bolt.

4. The rotary structure of a ceramic continuous slip casting apparatus according to claim 1, wherein: the upper end of the rotating shaft is fixedly connected with the tray, the lower end of the rotating shaft is connected with a transmission head, and the lower end surface of the transmission head is provided with a circle of tooth parts and is used as the power input end; the rotary driving mechanism comprises a power output shaft which is vertically arranged, the upper end of the power output shaft is connected with a face gear which is used as the power output end, and the face gear and the transmission head are vertically opposite and can be meshed with the circle of tooth parts;

or the transmission head connected with the lower end of the rotating shaft and the power output shaft of the rotary driving mechanism adopt non-gear transmission.

5. The rotary structure of a ceramic continuous slip casting apparatus according to claim 4, wherein: the face gear is a bevel gear, the lower end face of the transmission head is a conical surface which is concave inwards, and the circle of tooth parts are positioned on the conical surface and can be meshed with the bevel gear; or the concave friction wheel and the convex friction wheel are in friction engagement transmission.

6. The rotary structure of a ceramic continuous slip casting apparatus according to claim 5, wherein: the rotary driving mechanism comprises a mounting frame which is arranged below the die placing frame in parallel, a rotary power source is arranged on the mounting frame, the lower end of the power output shaft is connected with the rotary power source in a transmission manner, a lifting power source is vertically arranged below the mounting frame, and the telescopic end of the lifting power source is fixedly connected with the mounting frame so as to drive the mounting frame to lift.

7. The rotary structure of a ceramic continuous slip casting apparatus according to claim 6, wherein: the rotary power source is a motor, a rotary cylinder or a rotary hydraulic cylinder, and the lifting power source is a cylinder or a hydraulic driving cylinder.

8. The rotary structure of a ceramic continuous slip casting apparatus according to claim 7, wherein: the power output shaft is a flexible spring shaft.