JP5549884B2 - Drying equipment for the production of tiles or ceramics - Google Patents

Description

  The present invention relates to a drying apparatus for manufacturing tiles or ceramics, which dries a tile-shaped or plate-shaped substrate after wet forming.

  Holding means for holding a tile-shaped or plate-like substrate (specifically, a tile substrate) in a drying chamber formed by molding clay for clay or a mixture containing clay, and held by the holding device And a fan for generating a drying air in a transverse direction with respect to the substrate in the drying chamber, and a drying apparatus for tile production shown in Patent Document 1 for drying the substrate before firing with the drying air is known. .

JP-A-8-231263

In the above document, it is possible to promote the drying of the substrate by the drying air, but due to the non-uniform flow rate of the drying air, drying spots are generated on the substrate, resulting in deformation or cracking after drying, or after firing. May cause deformation or cracking of the material.
In the present invention, when drying a tile-shaped or plate-shaped substrate with a horizontal drying air generated by a fan before firing, drying spots are reduced, and a high-quality tile or plate-shaped ceramic is stably provided. It is an object of the present invention to provide a drying apparatus for manufacturing manufacturable roof tiles or ceramics.

  In order to solve the above-mentioned problem, first, holding means for holding a tile-shaped or plate-like substrate K formed by molding clay for baking or a mixture containing clay in the drying chamber 2, and the holding Manufacture of tiles or ceramics, comprising fans 8A and 8B for generating a drying air in a transverse direction with respect to the substrate K in the drying chamber 2 held by means, and drying the substrate K before firing with the drying air Rectifier for rectifying the drying air in the direction of blowing or sucking the drying air by the fans 8A and 8B between the base K held by the holding means and the fans 8A and 8B It is characterized by having been placed.

  Second, the rectifying unit is configured to perform rectification by regulating the vertical flow of the drying air.

  Third, the rectifying unit is configured to perform rectification by regulating the flow of the drying air in a direction intersecting the horizontal direction and intersecting the blowing direction or blowing direction of the drying air by the fans 8A and 8B. It is characterized by that.

  Fourthly, the rectifying unit is configured by forming a plurality of vent holes 22a penetrating the front and back in the rectifying plate 22 whose thickness direction is directed in the horizontal direction.

  Fifth, the vent hole 22a has a rectangular shape.

  Sixth, the plurality of vent holes 22a formed in a square shape are arranged in a lattice pattern.

  Seventh, the holding means is constituted by a rack 6 having a shelf 4 on which the substrate K is placed and held and having a lateral air permeability, and the fans 8A and 8B are arranged on the sides of the rack 6. It is characterized by that.

  Eighth, a pair of fans 8A and 8B that can be respectively located on both sides of the rack 6 constitute a drying set, and one fan 8A of the drying set is used as a blower fan, and the other fan 8B is By using the suction fan, the direction of the drying air generated by the pair of fans 8A and 8B is set in the same direction.

  Ninth, a plurality of the fans 8A and 8B are arranged along the transport path of the rack 6 configured to be transportable, and the direction of the dry air generated by one of the adjacent fans 8A and 8B in the transport path direction. And the direction of the drying air generated on the other side is set in the opposite direction with the rack 6 as a reference.

  According to the above configuration, the rectifying unit that rectifies the drying air in the blowing direction or the suction direction of the fan can suppress air turbulence and stably wake up the drying air in the lateral direction. Drying spots are reduced, and high-quality tiles or plate-shaped ceramics can be stably manufactured.

  Further, the holding means is constituted by a rack having a shelf for placing and holding the substrate and having a lateral air permeability, and the drying set is provided by a pair of fans that can be respectively positioned on both sides of the rack. If the direction of the drying air generated by the pair of fans is set to be the same by configuring one fan of the drying set as a blower fan and the other fan as a suction fan, the drying set By this, it is possible to generate a horizontal drying wind more stably.

  Further, a plurality of the fans are arranged along the transport path of the rack configured to be transportable, and the direction of the drying air generated by one of the adjacent fans in the transport path direction and the drying generated by the other If the direction of the wind is set to the opposite direction with respect to the rack, the direction of the drying air is alternately opposite to the rack being transported, so that dry spots are further reduced.

It is a flowchart which shows the manufacturing process of a clay roof tile. It is a conceptual diagram of the drying apparatus to which this invention is applied. It is a front view which shows the structure in the drying chamber of a drying apparatus. It is a side view which shows the structure of a pallet. It is a front view which shows the structure of each part of a movable fan. It is a side view which shows the structure of each part of a movable fan. (A) and (B) are the side view and front view of a baffle plate. (A), (B) is the side view and front view which show another embodiment of a baffle plate. It is a conceptual diagram shown in another embodiment of a drying apparatus. It is a conceptual diagram shown in another embodiment of a drying apparatus. (A) and (B) are the comparison graphs of the average value of the amount of tile warpage after drying, and the comparison graph of the standard deviation of the amount of tile warpage, when the current plate is used and when it is not used. It shows the wind speed of the vertical component of the dry wind when no rectifying plate is provided, (A) shows the wind speed of the vertical component of each part in the second stage from the top, and (B) shows each part in the ninth stage from the top. (C) shows the wind speed of the vertical component of each part in the 15th stage from the top. It shows the wind speed of the vertical component of the dry wind when the current plate is provided, (A) shows the wind speed of the vertical component of each part in the second stage from the top, and (B) shows each part in the ninth stage from the top. (C) shows the wind speed of the vertical component of each part in the 15th stage from the top.

Embodiments of the present invention will be described below based on the illustrated example.
FIG. 1 is a flowchart showing a manufacturing process of clay roof tiles. In the production of tiles or ceramics (specifically, tiles), the process first proceeds to step S1. In step S1, a plurality of types of clay suitable for roof tiles are mixed, and the process proceeds to step S2. Incidentally, in step S1, necessary components such as feldspar, quartz, porcelain stone, or nonstandard roof tile pulverized material may be added to the plurality of clays, and these may be mixed. In step S2, extrusion molding is performed, and the process proceeds to step S3. In step S3, the extruded molding is press-molded with a mold to form a tile base (base) having a tile shape, and the process proceeds to step S4. Incidentally, the shape of the tile assumed in step S2 and step S3 includes various types such as flat roof tiles, round roof tiles, and roof tiles in which the flat roof tiles and round roof tiles are integrated. It is.

  In step S4, the tile base is dried at a temperature of room temperature (approximately 25 ° C., although it varies depending on the season) to about 80 ° C., and the process proceeds to step S5. In step S5, the quality of the dried tile base is checked, and the quality that does not reach a certain level, such as large deformation such as twist due to drying, is removed, and the process proceeds to step S6. In step S6, glazing is applied to the dried tile base, and the process proceeds to step S7. In step S7, baking is performed, and the process proceeds to step S8. In step S8, the quality of the tile, which is a baked finished product, is checked, and the quality that does not reach a certain level, such as a large deformation such as twist due to firing, is removed, and the process proceeds to step S9. In step S9, a shipping process for tiles, which are finished products having a quality of a certain level or higher, is performed. By the way, the tile base to be discarded after drying is used again as raw clay.

  In the roof tile manufacturing process as described above, the drying apparatus to which the present invention is applied is used for drying the roof tile in step S4. Incidentally, the process of step S5 can be omitted, but by performing a quality check after drying and before firing, the manufacturing process can be checked with higher accuracy and after firing. It is possible to increase the yield.

  FIG. 2 is a conceptual diagram of a drying apparatus to which the present invention is applied, and FIG. 3 is a front view showing the configuration of the drying chamber of the drying apparatus. In the drying apparatus 1 for roof tile production, a drying chamber 2 serving as a tunnel is formed inside, and a transport rail 3 extending in the full length direction (front-rear direction) of the tunnel 2 is fixedly installed on the floor surface 2a side of the drying chamber 2, A transport rack (holding means, rack) 6 having a plurality of horizontal mounting shelves (shelves) 4 for mounting and holding the tile base K is slidably engaged in the drying chamber 1 by the transport rail 3. A movable rail 7 parallel to the transport rail 3 is installed on each of the right side of the rightmost transport rail 3 and the left side of the leftmost transport rail 3. A plurality of movable fans (fans) 8 are slidably engaged and supported on the movable rail 7 positioned at the position, and a plurality of movable fans 8 are also slidable on the movable rail 7 positioned to the right of the transport rail 7. Engage and support, inside drying chamber 2 Control means for controlling the temperature and humidity (not shown) are provided.

  Then, the drying device 1 is configured to remove the roof tile by horizontal (lateral) drying air generated by the movable fan 8 in the drying chamber 2 that is maintained at an optimum humidity and heated from room temperature to about 80 ° C. dry.

  The transport rack 6 is opened in the front and rear and left and right sides by stacking a plurality of rectangular mounting shelves 4 formed with a plurality of vertically divided support columns 4a with the four corners aligned. A rack frame 6a having a rectangular parallelepiped frame shape is formed, and a plurality of (8 in the illustrated example) are installed on each mounting shelf 4 and a transport device 9 that supports the rack frame 6a so as to be slidable on the transport rail 3. The pallet 11 is provided. Incidentally, a plurality of divided struts 4a are provided on the left and right end sides of the mounting shelf 4, respectively. Specifically, the divided struts are respectively provided on the front portion, the intermediate portion, and the rear portion on each end side. 4a is formed in the vertical direction one by one. For this reason, each mounting shelf 4 is provided with a total of six divided columns 4a.

  When the rack frame 6a is formed by stacking and supporting the mounting shelf 4, the divided struts 4a and 4a of the corresponding portions of the mounting shelves 4 and 4 that are adjacent in the vertical direction are engaged with each other on one side. The mounting shelves 4 and 4 are inserted and are opposed to each other through a predetermined interval in a state in which horizontal movement is restricted, and transported by the space between the mounting shelves 4 and 4 facing each other up and down. The rack 6 has a horizontal air permeability (lateral air permeability).

  The transport device 9 is composed of a pair of left and right wheels 12 and 12 that are pivotally supported on the lower end portion of the rack frame 6a. The transport device 9 is installed in two symmetrical positions on the left and right symmetrical positions on the lower end side of the rack frame 6a. The transport rack 6 is supported by a total of eight wheels 12. The pair of left and right wheels 12 and 12 of each transport device 9 are placed on the transport rails 3 and 3 in a state in which the left and right movements are restricted and rotated by being engaged with the pair of left and right transport rails 3 and 3. ing.

  That is, two transport rails 3 are installed at two symmetrical positions of the movable rack 6 in plan view. Incidentally, the respective members are arranged and configured so that the central portion in the left-right direction of the transport rack 6 and the central portion in the left-right direction of the drying chamber 2 match or substantially match.

  FIG. 4 is a side view showing the configuration of the pallet. The pallet 11 has a rectangular shape that is long in the front-rear direction along the transport path. On the pallet 11, holding parts 13 that place and hold the tile base K are positioned in the front-rear direction at predetermined intervals (equal intervals). A plurality (six in the illustrated example) are formed for each. A plurality (eight in the illustrated example) of pallets 11 are arranged in parallel on each mounting shelf 4 in the left-right direction with the front and rear positions aligned and parallel to each other. That is, it is possible to hold a total of 48 tile bases K in a grid pattern on each horizontal mounting shelf 4 in 8 × 6.

  Incidentally, in the illustrated example, the tile base material K is a tile base material for a flat-plate roof tile (hereinafter simply referred to as “flat roof tile”) referred to as an F type, and the flat tile tile base material K is illustrated in the figure of the holding unit 13. The positioning member that is not positioned is positioned and held by the holding portion 13 in a horizontal lying state. In addition to this, the flat roof tile base K held by the left half of the placement shelf 4 and the flat roof tile base K held by the right half are symmetrical to each other. Each pallet 11 is configured.

  In addition, when the pallet 11 is fixed to the mounting shelf 4 in a state where the front and back are reversed, the roof base material K for the roof tile can be positioned and held by the holding unit 13. Specifically, a plurality of protrusions 13a having different heights are formed along the wave shape of the roof tile base material K on the holding portion 13 whose front and back are reversed. One roof tile base K is placed and held on the projection 13a. As described above, the different types of the tile base material K can be held by the pallet 11 which is detachably attached to the rack frame 6a and can be turned upside down on the horizontal front and back surfaces.

Next, the configuration of the movable fan 8 will be described in detail with reference to FIGS.
As described above, the same number of movable fans 8 are arranged along the forming direction (conveyance path) of the conveyance rail 3 on the left side and the right side of the plurality of conveyance rails 3, 3, 3, 3 groups, respectively. The left and right movable fans 8 and 8 having the same or substantially the same front and rear position constitute a drying unit (drying set) 14 facing each other. In other words, the left and right movable fans 8, 8 of the drying unit 14 are opposed to each other with the transport rails 3, 3, 3, 3 arranged in parallel in plan view.

  A plurality of the drying units 14 are provided in the drying chamber 2 along the conveyance path in the above-described configuration, and the pair of left and right movable fans 8 and 8 constituting each drying unit 14 are in a positional relationship with each other. Are slid back and forth integrally so as to be held.

  In addition to this, among the drying units 14 arranged in parallel in the front-rear direction, the drying units 14 adjacent to each other in the front-rear direction have their movable ranges set so that the movable ranges do not overlap, and each drying unit 14 reciprocates back and forth within its movable range, positions the transport rack 6 between the left and right movable fans 8, 8, and a plurality of roof tiles K held by the transport rack 6. Then, the tile base K is dried by raising a drying air in the horizontal direction (specifically, the left-right direction).

  When this dry wind is raised against the tile base K held by the rack 6, one movable fan 8 of each drying unit 14 discharges air to the rack 6 side (tile base K side). (Blowout fan) 8A, and the other movable fan 8 becomes a suction fan (suction fan) 8B that blows air from the rack 6 side (the tile base K side), and is caused to wind by the two fans 8A and 8B. The direction of the drying air is set in the same direction.

  Also, the drying units 14 adjacent to each other in the front-rear direction, which is the conveyance path direction, of the respective drying units 14 so that the direction of the drying air to be raised is opposite to each other with respect to the conveyance rack 6. An exhaust fan 8A and a suction fan 8B are arranged. That is, when the transport rack 6 that is sequentially transported to the front side that is the downstream side reaches the predetermined drying unit 14, the drying air flows in the transport rack 6 from one side surface toward the other side surface. When the drying unit 14 is reached next to the drying unit 14, the drying air flows in the transport rack 6 from the other side surface toward the one side surface, and the reversal of the drying air is repeated.

  5 and 6 are a front view and a side view showing the configuration of each part of the movable fan. As shown in FIGS. 3, 5, and 6, the movable fan 8 that functions as the discharge fan 8 </ b> A or the suction fan 8 </ b> B is movable with a movable table 17 in the front-rear direction having a pair of left and right wheels 16, 16 in the front-rear direction. From a support frame 18 erected on the table 17, a plurality of blades 21 pivotally supported on the support frame 18 via a rotation shaft 19, iron, aluminum, stainless steel, or the like that rectifies the generated dry air And a rectifying plate (rectifying unit) 22 made of metal (iron in the illustrated example).

  A pair of left and right wheels 16, 16 arranged on the front and rear of the movable base 17 are engaged with the pair of left and right movable rails 7, 7 in a state in which the left-right movement is restricted, and is mounted on the movable rail 7 in a rotatable state. It is supported (see FIG. 3). Two movable rails 7 are arranged side by side on the left and right sides of the left and right symmetrical positions across the transport path of the transport rack 6. In other words, a total of four movable rails 7, 7, 7, 7 are installed on the floor side of the drying chamber 2, and two movable rails 7, 7 are arranged on the right side of the transport path, and on the left side. Two movable rails 7, 7 are arranged.

  The support frame 18 includes a pair of front and rear vertical frames 23 and 23 projecting upward from front and rear ends of the movable base 17, and a front and rear horizontal frame 24 fixed between the front and rear vertical frames 23 and 23. A vertical connecting frame 26 for connecting and fixing the middle part of the horizontal frame 24 and the movable base 17, a middle part of the front and rear vertical frames 23 and 23, and a middle part of the movable base 17, respectively. A pair of front and rear reinforcing frames 27 connected in an oblique direction is provided.

  The rotating shaft 19 is supported at the center in the front-rear direction on the horizontal frame 24 via a bearing 28 so as to be rotatable about its own axis. The blades 21 are evenly distributed around the axis of the rotating shaft 19 at equal intervals. Is installed. The drive motor 29 is driven by a transmission belt 32 that is wound around a drive pulley 31A that rotates integrally with an output shaft 29a of a drive motor 29 installed in the vertical frame 23, and a driven pulley 31B that rotates integrally with the rotary shaft 19. Power is transmitted to the rotating shaft 19, the blades 21 are driven to rotate, and the horizontal drying air is generated.

  Incidentally, the support frame 18, the bearing 28, the main driving pulley 31 </ b> A, the driven pulley 31 </ b> B, and the transmission belt 32 are disposed on the far side from the transport rack 6 (or the transport path of the transport rack 6) with respect to the blades 21. Is located outside the rotation trajectory of each blade 21.

  In addition, a semicircular arc-shaped upper cover 33 </ b> A that forms a mountain shape on the upper side around the rotation axis 19 in a side view along the upper half of the rotation locus of the blades 21, and the lower half of the rotation locus of the blades 21. A semicircular arc-shaped lower cover 33B having a valley shape on the lower side around the rotation shaft 19 in side view is attached and fixed to the support frame 18, and a plurality of upper and lower covers 33A and 33B The blades 21 are covered over the entire circumference of the rotary shaft 19, whereby the direction of the drying air generated by the rotation of the plurality of blades 21 is set in the left-right direction. In other words, the drying air is blown out or blown to the end surfaces of the upper cover 33A and the lower cover 33B on the side of the transport rack 6 (more precisely, the end near the transport path of the transport rack 6). A circular blowing surface or suction surface is formed.

  7A and 7B are a side view and a front view of the current plate. The unitized metal rectifying plate 22 is a rectangular plate-like member that is long in the front-rear direction and that faces in the left-right direction (lateral direction) in which the thickness direction is the flow direction of the drying air, and is entirely unitized. It is a current plate unit. This rectifying plate 22 has a rectangular vertical plate 36 that is long in the vertical direction when viewed from the front in a rectangular frame 34 along the entire outer shape at predetermined intervals in the front-rear direction (in the illustrated example, at regular intervals). And a plurality of horizontal plates 37 that are long in the front-rear direction in a plan view are arranged at predetermined intervals in the vertical direction (in the illustrated example, at equal intervals). A plurality of horizontal plates 37 intersect with each other in a lattice shape, thereby forming a plurality of rectangular air holes 22a arranged in a grid pattern in a side view.

  In the illustrated example, the air holes 22a are formed in a square shape. However, by forming the air holes 22a in a horizontal or slit shape in the horizontal direction (specifically, the front-rear direction), a rectifying effect described later can be obtained. It can be further increased. Further, the vertical plate 36 or the horizontal plate 37 may be arranged more densely than other portions in the portion where the flow rate of the drying air is high.

  In this way, the rectifying plate 22 has air permeability in the left-right direction, which is the thickness direction, by the plurality of air holes 22a arranged in a lattice pattern. That is, each air hole 22a is a left-right hole that penetrates the front and back of the current plate 22 in the shortest direction. When the dry air passes through the innumerable air holes 22a, the flow in the vertical direction is restricted. As a result, the upper and lower components of the wind speed of the drying wind are weakened, and only the horizontal component (specifically, the left and right components) is in a state where the strength is secured. That is, the rectifying plate 22 regulates the flow (turbulence) of the drying air in the direction (in this case, the up-down direction) deviating from the blowing or blowing direction of the drying air by the fan 8, and the drying air flows in the blowing or blowing direction. Is configured to rectify.

  Incidentally, since the air flow holes 22a are arranged in a lattice shape, the flow straightening plate 22 is a direction that intersects the blowing or blowing direction of the drying air by the fan 8 and that extends along the horizontal direction (illustrated). For example, it also has the effect of regulating the flow of dry air in the front-rear direction).

  In the illustrated example, the rectifying plate 22 is attached and fixed to the support frame 18 of the movable fan 8 so as to cover the lower half of the blowing surface or suction surface of the movable fan 8 (see FIG. 3). Preferably, it is preferable to cover the entire blowing surface or suction surface. However, as a result of wind speed measurement, it has been found that the drying air tends to be less disturbed in the upper half of the transport rack 6. For this reason, when the upper half is not covered with respect to the blowing surface or the suction surface of the movable fan 8 and only the lower half is covered with the rectifying plate 22, the influence of omitting the upper half is kept to a minimum. As a result, the overall weight can be easily reduced. Incidentally, the upper end of each movable fan 8 is close to the ceiling 2 b of the drying chamber 2, and the height of the upper end of the movable fan 8 is set to be slightly higher than the height of the upper end of the transport rack 6.

  The mounting structure of the rectifying plate 22 will be further described. A channel-like base member 38 that is long in the vertical direction is fixed to each of the front and rear ends of the frame frame 34 of the rectifying plate 22. 38 are attached and fixed to the front and rear vertical frames 23 and 23 via a pair of upper and lower prismatic fixed frames 39 and 39 extending in the left and right direction, respectively. In this attached state, the rectifying plate 22 is in a state of being close to or in contact with the lower cover 33B of the movable fan 8.

  At this time, rectification is performed so that the ceiling surface 4a formed on the lower surface side of the mounting shelf 4 on the upper stage of the mounting shelf 4 is flush with the upper end surface of the vent hole 22a positioned at a predetermined height. The mounting position of the plate 22 and the arrangement of the horizontal plates 37 are determined, whereby the rectifying action of the rectifying plate 22 can be further enhanced. Incidentally, when attaching to the current plate 22, the attachment position may be adjusted using a jig or the like.

  With the above-described configuration, the rectifying plate 22 is located between the roof tile K and the movable fan 8 when the drying unit 14 is positioned on the transport rack 6, and the drying air generated by the movable fan 8 is generated. As a result, the drying device 1 applies drying air from the lateral direction to each of the plurality of tile bodies K lying down in the lateral direction, thereby suppressing drying spots on the respective tile base bodies K. is there.

  The operation of the drying apparatus 1 configured as described above will be described. When the transport rack 6 holding a large number of tile bases K is introduced into the drying chamber 2, it is stopped for a predetermined time and a predetermined distance. Repeatedly the carrying operation carried by the minute. At this time, in one transport operation, the transport rack 9 is transported to the outlet side by one length. On the other hand, each drying unit 14 repeats reciprocating sliding movements continuously within its movable range with the blades 21 being rotationally driven. By such an operation, the tile base K is dried uniformly and without spots.

  In the above-described example, the drying units 14 and 14 that are adjacent in the front-rear direction, which is the conveyance path direction, have the directions of the drying air that wakes up in opposite directions with respect to the conveyance rack 6. The movable fans 8 wake up the drying air in the same direction with respect to the transport racks 6, and the rotation direction of the blades 21 of the movable fans 8 is reversed every predetermined time to reverse the direction of the drying air. You may let them.

  Furthermore, the illustrated drying apparatus 1 is not only for drying tiles, but also for drying the clay plate-shaped substrate formed into the shape in the stage before firing the plate-shaped ceramics such as tiles, flat plates, and the like. You may use for.

Next, based on FIG. 8, a different point from the above-mentioned example is demonstrated about another embodiment of the baffle plate 22. FIG.
FIGS. 8A and 8B are a side view and a front view showing another embodiment of the current plate. By arranging a plurality of vertical plates 36 at predetermined intervals in the front-rear direction in the frame frame 34 (at equal intervals in the example shown in the figure), a plurality of square-shaped vent holes 22 a arranged in the front-rear direction are formed in the rectifying plate 22. Is formed. The interval between the adjacent vertical plates 36 is set to be narrower than the example shown in FIG. 7. Specifically, the adjacent vertical plates 36 and 36 are formed so that the vent hole 22a forms a long slit shape in the vertical direction. The interval between them is set.

  And this baffle plate 22 is comprised so that it can be piled up and used in an up-down direction, Therefore, the up-down width is set short compared with the example shown in FIG.

  In addition, the current plate 22 may be hooked and detachably hooked on the side surface of the transport rack 6 with a hook-like member, or may be detachably pulled on the blowing surface or suction surface side of the movable fan 8. It may be hooked and locked, and may be fixed to the support frame 18 of the movable fan 8 using the base member 38 or the fixed frame 39 described above.

  The rectifying plate 22 configured as described above is in a direction intersecting with the blowing or blowing direction of the drying air by the fan 8 and in the horizontal direction by a plurality of vent holes 22a having a slit shape in the vertical direction. The flow of the drying air in the direction along the direction (the illustrated example, the front-rear direction) is regulated, and thereby, the drying air is rectified in the blowing or blowing direction.

  In this example, a plurality of vertical plates 36 arranged in the front-rear direction form the vent holes 22a in a slit shape that is long in the vertical direction. However, the horizontal plate 37 is arranged in the frame frame 34 at predetermined intervals in the vertical direction. The air holes 22a may be formed in a slit shape that is long in the horizontal direction by arranging a plurality of air holes (at equal intervals in the illustrated example). The rectifying plate 22 regulates the flow of the drying air in the vertical direction by the configuration, and thereby rectifies the drying air in the blowing or blowing direction.

Next, a different point from the above-mentioned example is demonstrated about another embodiment of the drying apparatus 1 based on FIG.
FIG. 9 is a conceptual diagram showing another embodiment of the drying device. In the example shown in the figure, in the drying chamber 2 of the drying apparatus 1, an annular transport path X having an oval shape in plan view is formed by the transport rail 3, and the transport path X or the vicinity thereof includes a transport path. A plurality of fans 8 are fixedly installed at predetermined intervals along the X direction. Specifically, the fan 8 is arranged along the longitudinal direction in the annular shape of the transport path X.

  Then, a horizontal drying air is generated from the side of the transport rack 6 circulated and transported on the transport path X by the fixed fan 8 to dry the tile base K. Specifically, the fan 8 is configured to blow air from one side and blow air from the other side to generate dry air on both sides. In the illustrated example, the dry air between adjacent fans 8 is Each fan 8 is configured to be alternately opposite. At this time, the rectifying plates 22 are individually installed on both sides of each fan 8 so that the above-described rectifying plates 22 are located between the fans 8 and the tile base K.

  Thus, even if the form of the drying apparatus 1 is changed, if the rectifying plate 22 shown in FIGS. 7 and 8 is used, a higher quality drying operation can be performed by the rectifying effect. The direction of the drying air generated by each fan 8 may be set to be the same, and the direction may be reversed every predetermined time, or the direction of the drying air is always set in the same direction. Also good.

Next, different points from the above-described example will be described with respect to another embodiment of the drying apparatus 1 based on FIG.
FIG. 10 is a conceptual diagram showing another embodiment of the drying device. In the example shown in the figure, a plurality of examples (specifically, three rows) of conveyance paths of one row shown in FIG. 2 are provided in the left-right direction. And the movable fan 8 is arrange | positioned between the row | line | column of a conveyance path | route, and the further outer side of the row | line | column of the conveyance path | route of the left-right outermost end, respectively.

  The movable fans 8 are arranged in a line in the left-right direction to form the above-described drying unit 14, and the drying unit 14 is configured to dry air in the same direction with respect to the transport racks 6 positioned therebetween. Is configured to wake up. At this time, the rectification 22 is installed on one side or both sides of each movable fan 8 so that the rectification plate 22 is positioned between each movable fan 8 and each transport rack 6.

  With this configuration, it is easy to dry a large amount of the tile base K at a stretch while maintaining the quality.

Next, the effect of the current plate 22 will be described based on FIG.
FIGS. 11A and 11B are a comparison graph of the average amount of tile warp after drying and a comparison graph of standard deviation of the amount of tile warp, when the current plate is used and when it is not used. . In this experiment, various conditions such as the temperature and humidity conditions of the drying chamber 2, the conditions of the drying air, the drying time, and the shape of the tile base K were the same, and the comparison was made based on the presence or absence of the rectifying plate 22.

  The drying apparatus 1 uses the one shown in FIG. 2, the rectifying plate 22 uses the one shown in FIG. Installed in half. The front and rear lengths of the current plates 22 are 2425 mm, the vertical width is 375 mm, the thickness is 38 mm, the vertical lengths of the air holes 22a are 315 mm, the front and rear width is 39 mm, and the drying unit 14 and the transport rack 6 are also It is installed in the size according to this.

  According to the result shown in FIG. 11, the tile base K of the mounting shelf 4 in the eighth to fifteenth stages from the top where the rectifying plate 22 is provided is more dry than that without the rectifying plate 22. The amount of warpage is reduced as a whole (quality is improved as a whole) (see (A) in the figure), and the variation in quality (variation in the amount of warpage) is also reduced as a whole (same as above). (Refer figure (B)). In particular, the variation in the quality of the tile base K during drying is drastically improved by the installation of the current plate 22.

Next, the effect of the rectifying plate 22 will be described with reference to FIGS.
FIG. 12 shows the wind speed of the vertical component of the dry wind when no current plate is provided, (A) shows the wind speed of the vertical component of each part in the second stage from the top, and (B) shows the wind speed of 9 from the top. The wind speed of the vertical component of each part in the stage is shown, and (C) shows the wind speed of the vertical component of each part in the 15th stage from the top. FIG. 13 shows the wind speed of the vertical component of the dry wind when the current plate is provided, (A) shows the wind speed of the vertical component of each part in the second stage from the top, and (B) shows the top speed. (C) shows the wind speed of the vertical component of each part in the 15th stage from the top.

  In this experiment, the drying apparatus 1 shown in FIG. 2 is used, and the current plate 22 shown in FIG. 7 is used. Specifically, the front and rear length of each current plate 22 is 3200 mm, the vertical width is 1502 mm, and the thickness is 50 mm. The vertical length of each air hole 22a is 190 mm, and the front and rear length is 182 mm. The drying unit 14 and the transport rack 6 are also installed according to this size, and the temperature and humidity conditions of the drying chamber 2 are also set. Experiments were performed under the same conditions such as the conditions of the drying air and the like.

  According to the results shown in FIG. 12 and FIG. 13, in the mounting shelf 4 at the 9th stage from the top and the mounting shelf 4 at the 15th stage from the top, when the rectifying plate 22 is not provided, Although the wind speed varies, when the rectifying plate 22 is provided, the variation in the wind speed of the vertical component in each part is suppressed, and the value is also suppressed as a whole, and good results are obtained. Incidentally, in the examples shown in these drawings, the drying air flows from the left side to the right side in the drawing.

  In addition, roof tiles were manufactured for a predetermined period under the same conditions. As a result, in the finished product after firing, a value obtained by subtracting the proportion of defective products due to deformation such as warpage when there is a current plate 22 from the proportion of defective products due to deformation such as warpage when there is no current plate 22 is + 3.7%, a significant improvement is seen, and the value obtained by subtracting the ratio of defective products due to cracks when the current plate 22 is present from the ratio of defective products due to cracks when the current plate 22 is present is +4. This was also 2%, which was a big improvement.

  Furthermore, as a result of investigating the yield after drying the tile base K with and without the use of the current plate 22 shown in FIG. 7, the case where the current plate 22 is used is more than the case where the current plate 22 is not used. 11.7% yield increased. The yield of the finished product obtained by firing the dried tile base K determined to be non-defective when the rectifying plate 22 is used is the same as the tile base K determined to be non-defective when the rectifying plate 22 is not used. The yield of the finished product obtained by firing was increased by 8.0%.

  Moreover, as a result of investigating the yield after drying the tile base K with and without the use of the current plate 22 shown in FIG. 8, the case where the current plate 22 is used is better than the case where the current plate 22 is not used. The value of 8.7% yield was high.

  From the above good results, it was proved that the tile base K and other plate-like bases can be stably dried while maintaining the quality. Thus, if the drying device 1 that does not operate continuously for 24 hours can stably supply a high-quality dried substrate, the time for securing a predetermined amount of dried substrate is shortened, and not only the labor cost can be deleted. In the finished product after firing, the ratio of defective products can also be reduced, so in the firing process of continuous operation for 24 hours, wasteful firing is reduced, and carbon dioxide for securing a predetermined amount of high-quality finished product Emissions can also be reduced. For this reason, it is environmentally friendly.

1 Drying equipment (drying equipment for roof tile production)
2 Drying room (tunnel)
2a Floor 2b Ceiling 3 Transport rail 4 Mounting shelf (shelf)
4a Dividing column 4b Ceiling surface 6 Transport rack (holding means, rack)
6a Rack frame 7 Movable rail 8 Movable fan (fan)
8A Discharge fan (Blowout fan)
8B Suction fan (suction fan)
9 Transport device 11 Pallet 12 Wheel 13 Holding part 13a Protrusion part 14 Drying unit (drying set)
16 Wheel 17 Movable stand 18 Support frame 19 Rotating shaft 21 Blade 22 Rectifier plate (rectifier)
22a Ventilation hole 23 Vertical frame 24 Horizontal frame 26 Connection frame 27 Reinforcement frame 28 Bearing 29 Drive motor (drive means)
29a Output shaft 31A Drive pulley 31B Drive pulley 32 Drive belt 33A Upper cover 33B Lower cover 34 Frame frame 36 Vertical plate 37 Horizontal plate 38 Base member 39 Fixed frame K Tile (base, flat tile, and roof tile)
X Transport route

Claims (9)

  Holding means for holding the tile-shaped or plate-like substrate (K) formed by molding clay for baking or clay-containing clay in the drying chamber (2), and a drying chamber held by the holding means (2) A roof tile that includes fans (8A) and (8B) for generating a drying air in a transverse direction with respect to the substrate (K) in the substrate, and for drying the substrate (K) before firing with the drying air. Or it is drying apparatus for ceramics manufacture, Comprising: Between the said base | substrate (K) hold | maintained by the holding means, and the fans (8A) and (8B), the blowing of the dry wind by a fan (8A) and (8B) A tile or ceramic drying apparatus provided with a rectifying unit for rectifying the drying air in the direction or suction direction.   The drying apparatus for manufacturing tiles or ceramics according to claim 1, wherein the rectifying unit is configured to perform rectification by restricting the vertical flow of the drying air.   The rectifying unit is configured to perform rectification by regulating the flow of the drying air in the direction intersecting the horizontal direction and intersecting the blowing direction or blowing direction of the drying air by the fans (8A) and (8B). 2. A drying apparatus for producing tiles or ceramics according to claim 1.   The tile or ceramic according to any one of claims 1 to 3, wherein the rectifying section is formed by forming a plurality of air holes (22a) penetrating the front and back of the rectifying plate (22) whose thickness direction is directed in the horizontal direction. Drying equipment for manufacturing.   The drying device for manufacturing tiles or ceramics according to claim 4, wherein the vent hole (22a) has a square shape.   6. A drying apparatus for producing tiles or ceramics according to claim 5, wherein a plurality of air holes (22a) formed in a square shape are arranged in a lattice pattern.   A rack (6) having a shelf (4) on which the substrate (K) is placed and held and having air permeability in the lateral direction is configured to form a holding means, and the fan ( The drying apparatus for producing tiles or ceramics according to any one of claims 1 to 6, wherein 8A) and (8B) are arranged.   A pair of fans (8A) and (8B) that can be positioned on both sides of the rack (6) constitute a drying set, and one fan (8A) of the drying set is used as a blower fan, and the other The fan (8B) is a suction fan, and the direction of the dry air generated by the pair of fans (8A) and (8B) is set in the same direction. Drying equipment   A plurality of the fans (8A) and (8B) are arranged along the transport path of the rack (6) configured to be transportable, and one of the fans (8A) and (8B) adjacent to each other in the transport path direction generates wind. The direction of the dry air to be generated and the direction of the dry air to be generated on the other side are set in opposite directions with reference to the rack (6), for producing tiles or ceramics according to any one of claims 1 to 8. Drying equipment.

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