JPH02138016A - Carrier of ceramic body - Google Patents

Abstract

PURPOSE:To prevent a ceramic body from being crushed by its own weight by a method wherein in an apparatus for floating and carrying a soft ceramic body immediately after extrusion, a recessed groove having an arc cross section for jetting gas pressure is provided lengthwise on an upper face of a receiving base, and gas pressure is applied asymmetrically along a periphery of the ceramic body. CONSTITUTION:A recessed groove 12 having an arc cross section is formed lengthwise on an upper face of a rectangular receiving base 11 made of high density polyethylene, and a rectangular air pressure chamber 13 is formed inside it so that compressed air is jetted by jet holes 14a to 14d. These jet holes 14a to 14d are arranged with a specified interval lengthwise and widthwise respectively, while the jet holes 14a to 14c are directed toward a center of the curvature of the recessed groove 12 and the jet hole 14d is formed so that it is out of the curvature center. This constitution makes a ceramic body 23 rotate with air from the jet hole 14d and carried by air from the other holes, thereby preventing the ceramic from being deformed.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a conveying device that conveys a ceramic body discharged in a horizontal direction and having a circular cross section in a floating state.

(Prior art) Ceramic bodies with a circular cross section, such as cylinders or cylinders, are often discharged laterally from an extruder and received on a conveyor.In this case, the ceramic bodies are soft and deformed immediately after being discharged. It is sometimes difficult to obtain a ceramic body (molded body) with high dimensional accuracy. In order to cope with this problem, Japanese Patent Publication No. 63-27163 discloses a device which levitates the ceramic body immediately after being discharged using the pressure of air jetted from a pedestal and conveys the ceramic body while maintaining this floating state.

(Problem to be Solved by the Invention) By the way, in the conveying device disclosed in the above-mentioned publication, the ceramic body is simply conveyed in a floating state using air pressure, so it may be crushed by its own weight before it hardens. Otherwise, deformation may occur.

Therefore, an object of the present invention is to prevent crushing deformation due to the weight of a ceramic body being conveyed in a floating state in this type of conveyance device.

(Means for Solving the Problems) A first aspect of the present invention is a conveying device of this type, which includes:
A groove with an arcuate cross section extending in the longitudinal direction of the pedestal and ejecting the gas is provided on the upper surface of the pedestal, and the gas pressure blown out from the circumferential surface of the groove is applied to the ceramic body asymmetrically in the circumferential direction. It is characterized by being given to.

Further, in a second aspect of the present invention, in the conveying device according to the first aspect, all or some of the plurality of gas jetting holes are oriented obliquely in the conveying direction of the ceramic body. It is characterized by being open.

Furthermore, the third aspect of the present invention is the above-mentioned first and second invention.
In the conveying device according to the invention, a gas having a high temperature of 40° C. or higher is employed as the gas, and the gas having the same temperature is ejected over the entire conveyance direction of the ceramic body, or the gas is gradually increased along the conveyance direction. It is characterized by sequentially ejecting hot gases.

Note that air, nitrogen gas, and other non-toxic and inert gases are used as the gas in the present invention.

(Operations and Effects of the Invention) In the conveying device of the first invention having such a configuration, the ceramic body having a circular cross section discharged from the extruder in the lateral direction is moved by the gas applied from below on the groove of the pedestal. Supported by pressure. Therefore, immediately after being discharged, the ceramic body cut into a predetermined length by a cutting means such as a piano wire is maintained in a floating state along the circumferential surface of the groove by gas pressure within the groove of the pedestal. Since the gas pressure is applied asymmetrically in the circumferential direction, rotational force is applied and the groove rotates along the circumferential surface of the groove. Therefore, after cutting the ceramic body to a predetermined length, the ceramic body is maintained in a floating state along the circumferential surface of the concave groove of the pedestal.In particular, since the ceramic body is transported while rotating, it can be cut to a predetermined length without being crushed and deformed due to its own weight. transported to the location.

In addition, in the conveying device of the second invention, all or some of the large number of jet holes are oriented obliquely in the conveying direction of the ceramic body, so that the gas spouted from these jet holes is The pressure acts as a thrust to move the ceramic body forward in the unloading direction, making it possible to transport the ceramic body without using any other special transport means.

Furthermore, in the conveying device of the third invention, since the ceramic body is pre-dried or completely dried by high-temperature gas during conveyance, the drying capacity of the conventional drying device is reduced and the size is reduced. or the drying device can be eliminated.

(Example) Examples of the present invention will be described below based on the drawings.
The figure shows a ceramic body conveying device according to a first embodiment of the present invention. The conveying device 10 consists of a long pedestal 11, which extends for a predetermined length from near the mouthpiece 21 of the extruder through the dryer 22, and is cut into a predetermined length by a cutting means (not shown) near the mouthpiece 21. The cut cylindrical ceramic body 23 is transported in the longitudinal direction.

The pedestal 11 is made of high-density polyethylene and has a rectangular parallelepiped shape, and as shown in FIGS. 2 to 4, a groove 12 having an arcuate cross section is formed in the center of the upper surface thereof. A pneumatic chamber 13 having a rectangular cross section is formed inside the air pressure chamber 13 . The groove 12 is slightly larger than the outer diameter of the ceramic body 23 to be discharged, and has substantially the same center of curvature. These grooves 12 and air pressure chambers 13 extend in the longitudinal direction of the pedestal 11, and four types of ejection holes 1 are provided between them 12 and 13.
4a to 14d are formed. Each jet hole 14a to 14
A large number of holes d are formed in a straight line at predetermined intervals in the longitudinal direction of the pedestal 11, and each row of the jet holes 14a to 14d maintains a predetermined interval in the width direction of the pedestal 11. Each of the ejection holes 14a to 14d is connected to the circumferential surface of the groove 12 and the air pressure chamber 1.
Each of the nozzle holes 14a to 14c forming the three rows of nozzle holes is oriented approximately at the center of curvature of the circumferential surface of the groove 12, and is open at the top of the nozzle hole group of the remaining one row. The ejection holes 14d forming the ejection hole group are oriented at predetermined positions offset from the center of curvature of the groove 12. In addition, each nozzle 1
4a to 14d are oriented obliquely in the conveying direction of the ceramic body 23.

Note that a pneumatic pump is connected to the pneumatic chamber 13, and compressed air of about 0.1 to 20 kg/am2 is supplied.

In the conveyance device 10 having such a configuration, each ejection hole 14a
Compressed air is blown out from ~14d, and the ceramic body 23 discharged from the mouthpiece 21 of the extruder is cut into a predetermined length near the mouthpiece 21 while floating from the pedestal 11 due to the jetted air pressure. Then, it is transported in a floating state into the dryer 22, and after drying, it is transported to a predetermined location.

In the conveying device 10, each of the ejection holes 14a to 14c forming the three rows of ejection hole groups is arranged in the groove 1.
The ceramic body 2 is oriented substantially at the center of curvature of the peripheral surface of the ceramic body
3, the ceramic body 23 is conveyed while being maintained in a floating state by the air pressure ejected from these ejection holes 14a to 14c. Moreover, since the ejection holes 14d forming one row of ejection holes are oriented at a portion offset from the center of curvature of the circumferential surface of the groove 12, the air pressure ejected from the ejection holes 14d causes the ceramic body to is rotated. Therefore, since the ceramic body 23 is conveyed while being maintained in a floating state and rotated, the ceramic body 23 is conveyed to a predetermined location without being crushed or deformed due to its own weight. Therefore, a ceramic body with high dimensional accuracy can be obtained, and there is no need to employ any other special means for conveying the ceramic body.

FIG. 5 shows a cross section of a main part of a conveying device 10A according to a second embodiment of the present invention. The pedestal 15 of the device 10A is made of a porous ceramic material, and the groove 1
The entire outer periphery except for the circumferential surface of groove 16 is sealed with glaze or the like, so that air pressure is ejected almost evenly from the circumferential surface of groove 16 through countless microscopic holes. As a result, the ceramic body 23 floats along the circumferential surface of the groove 16 and is maintained in a floating state. Further, the pedestal 15 is formed with an ejection hole 17 corresponding to the ejection hole 14d of the first embodiment, and the ceramic body 23 is conveyed while being rotated by the air pressure ejected from the ejection hole 17.

In each of the above embodiments, the ejection holes 14d and 17 direct air pressure to a portion deviated from the center of curvature of the circumferential surface of the groove as a means for imparting rotation in the circumferential direction to the ceramic body.
However, in the present invention, an appropriate means for applying gas pressure ejected from the circumferential surface of the groove to the outer periphery of the ceramic body asymmetrically in the circumferential direction to rotate the ceramic body may be adopted. Can be done. Further, in each of the above embodiments, high temperature air, nitrogen gas, etc. can be used. In particular, a metal material can be used as the material of the pedestal, but a gas having a temperature of about 40 to 150° C. can be used in relation to the material of the pedestal. For example, when air at about 85° C. is used, the ceramic body 23 is pre-dried to a considerable extent during transportation, so the drying capacity of the dryer 22 can be reduced and a smaller one can be used. .

FIG. 6 shows a conveying device 10B according to a third embodiment of the present invention. The conveying device 10B consists of an aluminum alloy pedestal 18 having the same cross-sectional shape as the pedestal 11 in the conveying device 10 of the first embodiment, an arcuate groove the same as the groove 12, and an air pressure chamber 13 having the same air pressure. Chamber, spout holes 14a-14
Each has the same four types of ejection holes as d. Thus, the air pressure chamber of the pedestal 18 is divided into three in the longitudinal direction, and each compartment 18a, 18c has an air inflow hole 19a.
l, 19bt 19cl and outflow hole 19a2.19
b2.19C2 are communicating with each other. 1st compartment 1
8a has air at about 40°C, and second compartment 18b has air at about 80°C.
℃ air and approximately 100 ℃ air is supplied to the third compartment 18c. In the conveying device 10B, similarly to the conveying device 10 of the first embodiment, the ceramic body 23 is conveyed while being rotated in a floating state due to the action of the ejected air, but the temperature changes in three stages during conveyance. Since the entire circumference is evenly exposed to air, it is completely dried by the time it reaches the designated position.

Therefore, in the conveying device 10B, both the special conveying means and the drying device can be abolished.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of a conveying device according to a first embodiment of the present invention;
FIG. 2 is an enlarged longitudinal sectional front view of the same, FIG. 3 is a partial longitudinal sectional side view, FIG. 4 is a partial plan view of the same, and FIG. 5 is a longitudinal sectional front corresponding to FIG. FIG. 6 is a perspective view corresponding to FIG. 1 of a conveying device according to a third embodiment of the present invention. Explanation of symbols 10.10A, IOB...transport device, 11.15.1
8... pedestal, 12. 16... groove, 13... pneumatic chamber, 14a to 14d, 17. nozzle hole, 18a to 18c
... compartment, 21... cap, 23... ceramic body. 2 to 5 10, IOA Transfer device 11.15 pedestal 1216 groove 13 pneumatic chambers 14a-14d, 17, ejection hole 23 ceramic body

Claims (3)

[Claims] (1) A pedestal of a predetermined length is provided with a large number of ejection holes that eject gas such as air, and a ceramic body with a circular cross section that is ejected laterally is floated from the pedestal by the pressure of the ejected gas. In a conveying device for a ceramic body that conveys a ceramic body in a state, a groove having an arcuate cross section extending in the longitudinal direction of the pedestal and ejecting the gas is provided on the upper surface side of the pedestal, and the gas is ejected from the circumferential surface of the groove. A conveying device for a ceramic body, characterized in that gas pressure is applied to the ceramic body asymmetrically in a circumferential direction. (2) In the conveying device according to item 1, all or some of the large number of gas jetting holes are opened and oriented in an inclined manner in the conveying direction of the ceramic body. A device for transporting ceramic bodies. (3) In the conveyance device according to item 1 or 2,
A gas with a high temperature of 40° C. or more is used as the gas, and the gas with the same temperature is ejected over the entire conveyance direction of the ceramic body, or the gas with a high temperature is sequentially ejected in stages along the conveyance direction. A conveying device for a ceramic body characterized by ejecting it.