JP7173945B2 - Heat treatment equipment - Google Patents

Description

The present invention relates to a heat treatment apparatus.

2. Description of the Related Art Conventionally, there has been proposed a heat treatment apparatus in which a web such as a film or fabric is transported into a heat treatment chamber in a spread state by a tenter device, and the transported web is heat-treated by blowing hot air from nozzles in the heat treatment chamber.

JP 2014-172275 A

When hot air is blown from the nozzles onto the web being conveyed in a spread state by the tenter device, there is a problem that it is difficult to apply the hot air uniformly in the width direction of the web.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide a heat treatment apparatus having a heat treatment chamber capable of uniformly blowing hot air in the width direction to a web being conveyed in a spread state by a tenter device. .

The present invention comprises a pair of left and right tenter rails, a pair of left and right endless tenter chains arranged along the pair of left and right tenter rails, a chain driving means for moving the pair of left and right tenter chains in the front-rear direction, The web is supported from both left and right sides, respectively, is provided on the pair of left and right tenter chains at predetermined intervals, and travels along the pair of left and right tenter rails by moving the pair of left and right tenter chains, A tenter device having a plurality of pairs of left and right support means for transporting the web from front to back, and one or more heat treatment chambers for heat-treating the web transported in the front-rear direction, in which the pair of left and right tenter rails are accommodated. and the heat treatment chamber includes an upper duct provided along the front-rear direction above the conveying path of the web, and a lower portion of the upper duct provided at predetermined intervals to blow hot air onto the web from above. a lower duct provided along the front-rear direction below the conveying path; a lower nozzle provided at predetermined intervals above the lower duct for blowing hot air onto the web from below; An upper left fan that supplies hot air to the left side in the upper duct, an upper right fan that supplies hot air to the right side in the upper duct, a lower left fan that supplies hot air to the left side in the lower duct, and the lower duct. provided between a lower right fan for supplying hot air to the right side of the interior, the lower duct in the heat treatment chamber, and the carrying-in or carrying-out portion of the web in the heat treatment chamber, and supports the pair of left and right tenter rails. The pair of left and right tenter rails includes a plurality of pairs of left and right partial rails, and a connecting movement means for moving the connecting portion of the adjacent partial rails in the front-rear direction and the left-right direction. and the connecting and moving means is supported by the tenter support portion . Further, the present invention includes a pair of left and right tenter rails, a pair of left and right endless tenter chains arranged along the pair of left and right tenter rails, and chain driving means for moving the pair of left and right tenter chains in the front-rear direction. The web is supported from both left and right sides, respectively, is provided on the pair of left and right tenter chains at predetermined intervals, and travels along the pair of left and right tenter rails by moving the pair of left and right tenter chains. , a plurality of left and right support means for transporting the web from front to back, and one or more heat treatment chambers for heat-treating the web transported in the front-rear direction, in which the pair of left and right tenter rails are housed. The heat treatment chamber includes an upper duct provided along the front-rear direction above the conveying path of the web, and upper nozzles provided at predetermined intervals below the upper duct for blowing hot air onto the web from above. a lower duct provided along the front-rear direction below the conveying path; and lower nozzles provided at predetermined intervals above the lower duct for blowing hot air onto the web from below; A tenter supporting portion for supporting the pair of left and right tenter rails is provided between the lower duct in the chamber and the web carry-in or carry-out portion in the heat treatment chamber, and the pair of left and right tenter rails are provided with a plurality of sets of tenter rails. A heat treatment apparatus comprising a pair of left and right partial rails, and connecting movement means for moving connecting portions of the adjacent partial rails in the front-rear direction and the left-right direction, wherein the connection moving means is supported by the tenter support portion. It is a device.

According to the present invention, hot air is blown from each of the upper, lower, left, and right fans to the web being conveyed in the heat treatment chamber in a spread state by the tenter device, so that the web can be uniformly heat treated in the width direction. .

It is a side view of the heat processing apparatus of this embodiment. It is a top view of a heat processing apparatus. It is the longitudinal cross-sectional view seen from the side of the heat treatment chamber. It is the longitudinal cross-sectional view seen from the front of the heat treatment chamber. It is a cross-sectional view of a heat treatment chamber. FIG. 4 is a plan view of the partial rail in a straight state; FIG. 4 is a plan view of the partial rail in an inclined state; FIG. 4 is a plan view of a connecting portion of the partial rail in a straight state; FIG. 4 is a plan view of a connecting portion of a partial rail in an inclined state; FIG. 9 is a cross-sectional view taken along the line AA in FIG. 8; FIG. 9 is a cross-sectional view taken along the line BB in FIG. 8, with a pair of left and right clips added. It is an exploded perspective view of a front spring board, a back spring board, and a middle spring board. (a) is a side view of the straight front spring plate, (b) is the farthest state between the first front spring plate and the second front spring plate, and (c) is the closest side view of the front spring plate. is. (a) is a state in which the first back spring plate and the second back spring plate are closest to each other, (b) is a state in which they are farthest apart, and (c) is a side view of the back spring plate in a linear state. . It is a top view which shows the relationship between a pair of right-and-left male screw part and a pair of right-and-left connection motor. 1 is a block diagram of a heat treatment apparatus; FIG.

A heat treatment apparatus 1 according to an embodiment of the present invention will be described below with reference to FIGS. 1 to 16. FIG. The heat treatment apparatus 1 of the present embodiment includes a tenter device 10 that conveys a web in a spread state, and a plurality of tenter devices 10 that house the tenter device 10 and perform heat treatment by blowing hot air onto the spread web. and a heat treatment chamber 5 . A plurality of heat treatment chambers 5 are arranged in series along the web transport direction of the tenter device 10 . The tenter device 10 in this embodiment will be described as a clip tenter device that grips both sides of a web with clips.

In this embodiment, a film F is used as a long web. As this film F, a thermoplastic resin such as a polymer film used for a polarizing plate can be used. Examples of polymers include polyvinyl alcohol, polycarbonate, cellulose acylate, polysulfone, and the like. The film F may also be polyester, polyethersulfone, polystyrene, polyolefin, polyvinyl alcohol, cellulose acetate, polyvinyl chloride, polymethyl methacrylate, polyarylate, polyamide, or the like. Furthermore, the film F has an ultraviolet absorption function like a film treated with an ultraviolet absorber such as a salicylic acid ester compound, a benzophenol compound, a benzotriazole compound, a cyanoacrylate compound, a nickel complex compound, or the like. can be anything.

Among them, polycarbonate-based resins, polystyrene-based resins, and polynorbornene-based resins are preferable. Polynorbornene-based resins are particularly preferred because they have a relatively small photoelastic coefficient, are flexible, and are less susceptible to cracking or tearing due to bending stress or shearing stress. The weight-average molecular weight of the thermoplastic resin is not particularly limited, and an appropriate one can be used.

(1) Structure of tenter device 10 The overall structure of the tenter device 10 will be described with reference to FIGS. 1 and 2. FIG. The tenter device 10 of the present embodiment can be changed from a lateral stretching device to a diagonal stretching device, or from a diagonal stretching device to a lateral stretching device. FIG. 2 is a plan view of an apparatus for lateral stretching.

In the following description, it is assumed that the conveying path of the tenter device 10 is provided on the xy plane in the xy orthogonal coordinate system, the film F runs on the xy plane (on the horizontal plane), and the front-rear direction is the y-axis. , and the horizontal direction is parallel to the x-axis.

The tenter device 10 has a pair of left and right tenter rails 16, 16 along the transport path of the film F. As shown in FIG. A driven sprocket 18 is provided on the carry-in side of the left tenter rail 16, and a driving sprocket 20 is provided on the carry-out side. An endless tenter chain 22 is stretched over the driven sprocket 18 and the drive sprocket 20 . The tenter chain 22 is provided with a clip 24 for gripping the left ear portion of the film F at predetermined intervals. Note that the illustration of the clip 24 is partially omitted in FIG. The tenter rail 16 on the right has a similar structure. A pair of left and right drive sprockets 20 are rotated by a drive motor 26 .

The left tenter rail 16 has, for example, nine partial rails 28 connected by the connecting portion 4 , and the right tenter rail 16 likewise has nine partial rails 28 connected by the connecting portion 4 .

The tenter device 10 can be changed to a lateral stretching device or an oblique stretching device by moving the connecting portion 4 of the partial rails 28 in the x-axis direction (horizontal direction).

As shown in FIG. 2, in the device for lateral stretching, the distance between the sixth pair of left and right tenter rails 16, 16 widens symmetrically as it goes from the entrance to the exit, and the film F is laterally stretched. . The center line C of the pair of left and right partial rails 28 of the device for lateral stretching is always parallel to the y-axis.

When diagonal stretching is performed by the tenter device 10, the distance between the fifth and sixth pair of left and right tenter rails 16, 16 becomes wider as it goes from the carry-in port to the carry-out port, and the pair of left and right rails with respect to the y-axis direction. The center line C of the partial rail 28 is inclined by θ°, and the film F is obliquely stretched. However, 0°<θ°<=45°.

(2) Structure of Heat Treatment Chamber 5 Next, the structure of the heat treatment chamber 5 will be described with reference to FIGS. 1 to 5. FIG.

As shown in FIG. 1, a plurality of heat treatment chambers 5 are mounted on a base 6 provided on a horizontal floor, and arranged in series along tenter rails 16 as shown in FIGS. ing.

Each heat treatment chamber 5 has a heat insulating structure, and has a ceiling surface 150 , a bottom surface 152 and left and right side surfaces 154 and 156 . Adjacent heat treatment chambers 5 are connected via a partition wall, and the partition wall has openings through which the pair of left and right tenter rails 16 and the film F pass. A front wall is provided on the front surface of the heat treatment chamber 5 closest to the carry-in entrance side, and a pair of left and right tenter rails 16 and an entrance for the film F carried in by the tenter rails 16 are opened. A rear wall is provided on the rear surface of the heat treatment chamber 5 closest to the exit, and a pair of left and right tenter rails 16 and an exit for the film F conveyed by the tenter rails 16 are opened. A pair of left and right tenter rails 16 on both sides of the transport path of the film F inside the heat treatment chamber 5 are composed of a plurality of partial rails 28 .

As shown in FIGS. 3 to 5, an upper duct 160 is arranged in the front-rear direction above the transfer path in the heat treatment chamber 5. As shown in FIGS. Upper nozzles 162 are provided laterally at predetermined intervals from the lower surface of the upper duct 160 . A plurality of upper nozzles 162 are provided at predetermined intervals along the front-rear direction.

A pair of left and right connecting portions 164 and 166 are provided on the upper surface of the front portion of the upper duct 160 .

An upper left filter 168 is provided on the upper left connecting portion 164 above the upper left connecting portion 164 . An upper right filter 170 is also provided above the upper right connecting portion 166 .

A pair of left and right upper left fans 172 and upper right fans 174 are provided at the rear of the ceiling surface 150 .

Below the ceiling surface 150 are divided into four compartments 176-182. An upper left filter 168 is accommodated in the left front compartment 176, an upper right filter 170 is accommodated in the right front compartment 180, and an upper left fan 172 is accommodated in the left rear compartment 178. , and an upper right fan 174 is housed in the compartment 182 on the right rear side. An upper left heater 184 is provided on the left side of the left rear compartment 178 , and an upper right heater 186 is provided on the right side of the right rear compartment 182 .

As shown in FIGS. 3 to 5, a lower duct 260 is arranged in the front-rear direction below the transfer path in the heat treatment chamber 5 . Lower nozzles 262 are provided laterally at predetermined intervals from the upper surface of the lower duct 260 . A plurality of lower nozzles 262 are provided at predetermined intervals along the front-rear direction.

A pair of left and right connecting portions 264 and 266 are provided on the lower surface of the front portion of the lower duct 260 .

A lower left filter 268 is provided in the lower left connecting portion 264 below the lower left connecting portion 264 . A lower right filter 270 is also provided below the lower right connecting portion 266 .

A pair of left and right lower left fans 272 and lower right fans 274 are provided at the rear portion of the bottom surface 152 .

Above the bottom surface 152 are divided into four compartments 276-282. A lower left filter 268 is accommodated in the compartment 276 on the left front side, a lower right filter 270 is accommodated in the compartment 280 on the right front side, and a lower left fan 272 is accommodated in the compartment 278 on the left rear side. A lower right fan 274 is housed in the compartment 282 on the right rear side. A lower left heater 284 is provided on the left side of the left rear compartment 278 , and a lower right heater 286 is provided on the right side of the right rear compartment 282 .

A pressure sensor 196 for measuring the pressure inside the heat treatment chamber 5 is provided inside the right side surface 156, as shown in FIG.

An upper temperature sensor 158 is provided inside one upper nozzle 162 as shown in FIG. A lower temperature sensor 258 is provided inside one lower nozzle 262 as shown in FIG.

As shown in FIG. 5 , a pair of left and right air supply ports 188 and 190 are provided on both left and right sides of the rear end portion of the ceiling surface 150 . A pair of left and right exhaust ports 192 and 194 are provided on both left and right sides of the front end portion of the ceiling surface 150 .

As shown in FIG. 1, a main air supply pipe 200 is arranged above the plurality of heat treatment chambers 5 along the front-rear direction. Air supply connecting pipes 202, 202 provided from a pair of left and right air supply ports 188, 190 in each heat treatment chamber 5 are connected, respectively. As shown in FIG. 4, an air supply damper 204 is built in each of the main air supply pipes 200 to which the air supply connection pipes 202, 202 are connected, so that the amount of air supplied to the air supply ports 188, 190 can be adjusted. Air is supplied in such a manner that the suction force of the upper left fan 172, the upper right fan 174, the lower left fan 272, and the lower right fan 274 allows the air to flow naturally through the main air supply pipe 200. FIG.

As shown in FIG. 1, a main exhaust pipe 206 is arranged along the front-rear direction above the heat treatment chambers 5 . Exhaust connection pipes 208 , 208 are provided from a pair of left and right exhaust ports 192 , 194 of each heat treatment chamber 5 , respectively, and are connected to the main exhaust pipe 206 . The rear end of the main exhaust pipe 206 is provided with an exhaust device (for example, a blower) 212 for forced exhaust.

As shown in FIG. 3, the length of the lower duct 260 in the front-rear direction is shorter than the length of the upper duct 160 and does not reach the rear end portion (unloading portion) of the heat treatment chamber 5 . In the space between the rear end portion of the lower duct 260 and the rear end portion (unloading portion) of the heat treatment chamber 5 , a tenter support 214 is vertically erected from the bottom surface 152 of the heat treatment chamber 5 . The tenter support 214 supports the connecting portion 4 of the tenter device 10, which will be described later. An upper duct 160 and an upper nozzle 162 are present above the tenter support 214 , and the upper duct 160 extends to the rear end of the heat treatment chamber 5 (unloading portion).

(3) Structure of Inlet and Outlet Next, the structure of the tenter device 10 at the inlet and outlet of the film F will be described with reference to FIGS. 1 and 2 and FIG.

At the entrance of the tenter device 10, there are an entrance table 34 fixed to the floor as a driven moving means, a driven table 30 on the entrance table 34, and a pair of left and right driven slide plates 31, 31 on the driven table 30. A pair of left and right driven slide plates 31, 31 are provided with a pair of left and right driven sprockets 18, 18, respectively. The driven sprocket 18 rotates as the tenter chain 22 moves. A pair of left and right driven slide plates 31 are arranged on the driven table 30 via left and right rails 33 so as to be independently movable in the left and right direction. As a result, the driven slide plate 31 having the driven sprocket 18 is independently moved left and right on the driven table 30 by the driven slide motor 25 . The driven table 30 is mounted on the entrance table 34 so as to be movable in the longitudinal direction via the front and rear rails 32. When the driven sprockets 18, 18 and the partial rail 28 are pulled rearward, the driven table 30 moves along the front and rear rails 32 along with it. As a result, the driven table 30 moves rearward. However, the driven table 30 does not move beyond the front and rear ends of the front and rear rails 32 .

At the carry-out port of the tenter device 10, there are an exit table 42 fixed to the floor which is a drive moving means, a drive table 38 above the exit table 42, and a pair of left and right drive slide plates 36, 36 above the drive table 38. A pair of left and right drive slide plates 36, 36 are provided with a pair of left and right drive sprockets 20, 20, respectively. Drive sprocket 20 is rotated at a predetermined rotational speed by drive motor 26 . A pair of left and right drive slide plates 36 are arranged on a drive table 38 via left and right rails 40 so as to be independently movable in the left and right direction. As a result, the drive slide plate 36 having the drive sprocket 20 is independently moved left and right on the drive table 38 by the drive slide motor 37 . In addition, the drive table 38 is disposed on the exit table 42 so as to be movable in the front-rear direction via a linear way 44. The linear way 44 rotates a male threaded rod 48 connected to a positioning motor 46, thereby The drive table 38 is moved forward and backward with respect to the exit table 42 .

(4) Structure of Connection Portion 4 Next, the structure of the connection portion 4 of the partial rails 28, 28 will be described with reference to FIGS. 6 to 11. FIG. Hereinafter, one of the adjacent partial rails 28, 28 will be referred to as the first partial rail 28, and the other adjacent partial rail 28 will be referred to as the second partial rail 28, in order to facilitate understanding of the description.

As shown in FIGS. 8 and 9, both the first partial rail 28 and the second partial rail 28 are horizontally arranged, and vertical rails 27, 27 are erected on both left and right sides of the upper surface. The flat upper surface of the side rail 29 is constructed.

As shown in FIGS. 8 and 9, shaft holes 50 are opened at both front and rear end portions of the first partial rail 28, and axial holes 50 are also opened at both front and rear end portions of the second partial rail 28 in the vertical direction. . As shown in FIG. 8, a connecting shaft 52 vertically passes through the shaft hole 50 of the first partial rail 28 and the shaft hole 50 of the second partial rail 28 to rotate the first partial rail 28 and the second partial rail 28. movably connected.

As shown in FIGS. 10 and 11, the connecting shaft 52 is erected vertically from the connecting slide plate 54 . The connecting slide plate 54 is movable in the front-rear direction with respect to the connecting base 56 . Specifically, as shown in FIGS. 6 and 7, a long hole 58 is provided in the connecting base 56 in the front-rear direction, and a projection 60 protrudes downward from the connecting slide plate 54. The projection 60 extends along the long hole 58. It is movable.

As shown in FIGS. 10 and 11, the connecting base 56 can be moved horizontally by wheels 64 on support rails 62 fixed to the floor. A screw receiving portion 66 through which a female screw portion 67 penetrates in the left-right direction is provided on the lower surface of the connecting base 56 , and a male screw portion 68 provided in the left-right direction penetrates the female screw portion 67 of the screw receiving portion 66 . there is The male screw portion 68 is rotated by a coupling motor 70, which is coupling base moving means. As a result, the connecting base 56 moves laterally on the support rail 62 .

As shown in FIG. 15, a pair of left and right male screw portions 68, 68 screwed together with female screw portions 67, 67 of a pair of left and right connecting bases 56 are threaded in opposite directions. ing. The inner ends of the pair of left and right male screw portions 68, 68 are rotatably attached to a pair of left and right independent bearings 112, 112 provided in the center of the heat treatment chamber 5. Outer ends of 68 protrude from left and right side surfaces 154 and 156 of the heat treatment chamber 5, respectively, and are connected to a pair of left and right connecting motors 70 and 70 outside the left and right side surfaces 154 and 156, respectively. When the pair of left and right connecting motors 70, 70 rotates, the pair of left and right male screw portions 68, 68 whose threading directions are opposite to each other rotate symmetrically to each other by the pair of left and right bearings 112, 112, and the pair of left and right connecting bases 56 rotate. , 56 move symmetrically. Note that the coupling motor 70 may include a reduction gear or the like.

In addition, as this modification, the inner ends of the pair of left and right male screw portions 68, 68 are connected via a coupling device, and one male screw portion 68 of the pair of left and right male screw portions 68, 68 is connected. Only the outer end portion is protruded from the side surface of the heat treatment chamber 5 and connected to the connection motor 70 . Then, when one connecting motor 70 rotates, the pair of left and right male threaded portions 68, 68 whose threading directions are opposite to each other rotate symmetrically with respect to each other with the coupling device interposed therebetween, and the pair of left and right connecting bases 56, 56 rotate. Move symmetrically.

As shown in FIG. 10 , the upper surface of the connecting shaft 52 is a flat surface and is at the same height as the lateral rails 29 of the partial rails 28 .

When the connecting motor 70 is rotated from the state in which the pair of left and right partial rails 28 are straight as shown in FIGS. , the end of the first partial rail 28 rotates about the connecting shaft 52 and is inclined with respect to the second partial rail 28 . In addition, the inclination angle of the partial rail 28 is proportional to the moving distance of the connecting base 56 . Further, since the connecting motor 70 is a servomotor, the moving distance of the connecting base 56 is proportional to the rotation angle of the connecting motor 70 . The inclination angle of the partial rail 28 is therefore proportional to the rotation angle of the coupling motor 70 .

(5) Structure of the Gap Between the First Partial Rail 28 and the Second Partial Rail 28 Next, the structure of the gap between the first partial rail 28 and the second partial rail 28 will be described.

A gap is formed between the first partial rail 28 and the second partial rail 28 . Therefore, a bendable guide plate 72 spans over this gap so that the clip 24 can move. This guide plate will be described with reference to FIGS. 12 to 14. FIG.

The guide plate 72 has a three-layer structure of a front spring plate 74 , a rear spring plate 76 and a middle spring plate 78 .

As shown in FIG. 12, the front spring plate 74 is composed of a first front spring plate 74a and a second front spring plate 74b. As shown in FIG. 13, one end of the first front spring plate 74a on the entrance side is fixed by a bolt 83, and the other end is a free end. A projecting piece 80 protrudes in the front-rear direction from the lower portion of the free end of the first front spring plate 74a. On the other hand, one end of the second front spring plate 74b on the outlet side is fixed by a bolt 83, and the other end is a free end. A U-shaped concave portion 82 into which the projecting piece 80 is inserted is formed in the front-rear direction at the free end of the second front spring plate 74b. The length of the concave portion 82 in the front-rear direction is longer than the length of the projecting piece 80 in the front-rear direction. The upper side of the projecting piece 80 at the free end of the first front spring plate 74a and the upper side of the concave portion 82 of the second front spring plate 74b are pressed and fixed by a pressing plate 84. As shown in FIG. However, the projecting piece 80 is movable in the front-rear direction with respect to the pressing plate 84 .

As shown in FIG. 12, the back spring plate 76 is composed of a first back spring plate 76a and a second back spring plate 76b. As shown in FIG. 14, one end of the first back spring plate 76a on the carry-out port side is fixed by a bolt 87, and the other end on the carry-in port side is a free end. A projecting piece 86 protrudes in the front-rear direction from the upper portion of the free end of the first back spring plate 76a. One end of the second back spring plate 76b on the outlet side is fixed by a bolt 87, and the other end is formed with a U-shaped concave portion 88 into which the projecting piece 86 is inserted. The projecting piece 86 is formed above the first back spring plate 76a as described above, and is formed vertically different from the projecting piece 80 of the first front spring plate 74a (see FIG. 12). The dimension of the recess 88 is formed to be longer than the dimension of the projecting piece 86, and this difference in dimension allows the projecting piece 86 to slide and the guide plate 72 to be curved. The lower side of the projecting piece 86, which is a free end, is pressed against the lower side of the recess 88 by a pressing plate 90 and fixed. However, the projecting piece 86 is movable in the front-rear direction with respect to the pressing plate 90 .

As shown in FIG. 12, a middle spring plate 78 is sandwiched between the front spring plate 74 and the rear spring plate 76 to reinforce the strength. However, the length of the middle spring plate 78 in the front-rear direction is shorter than the lengths of the front spring plate 74 and the rear spring plate 76 .

Due to the difference in dimension between the projecting piece 80 and the recessed portion 82 and the difference in dimension between the projecting piece 86 and the recessed portion 88, even when the guide plate 72 is straight as shown in FIG. Even when the guide plate 72 is curved as shown, the gap between the first partial rail 28 and the second partial rail 28 can be connected by sliding the projecting piece 86 and the recessed portion 88 and the projecting piece 80 and the recessed portion 82 .

(6) Structure of Clip 24 Next, the structure of the clip 24, which is means for supporting the film F, will be described with reference to FIG.

The clip 24 is provided with an inverted U-shaped gripping portion 94 at the upper end portion of a U-shaped clip base 92, and is rotatably gripped at the upper end portion of the inverted U-shaped gripping portion 94. A bar 96 is provided. As the gripping rod 96 rotates, the film F is gripped by the gripping rod 96 and the lower portion of the gripping portion 94 .

The clip base 92 has a tenter chain 22 provided inside a U-shaped concave portion 98 . A first running wheel 100 is rotatably provided below the recess 98 . The rotation axis of the first running wheel 100 is vertical.

An extending portion 102 protrudes inward from the clip base 92, and a second running wheel 104 is rotatably provided under the extending portion 102. As shown in FIG. The rotation axis of the second running wheel 104 is vertical. Furthermore, a third running wheel 106 is provided outside the extended portion 102 . The rotation axis of the third running wheel 106 is horizontal.

The first running wheel 100 of the clip base 92 runs along the vertical rail 27 of the partial rail 28 and the front spring plate 74 of the guide plate 72, and the second running wheel 104 runs along the vertical rail 27 of the partial rail 28 and the guide plate. 72 , and the third running wheel 106 runs on the upper surface of the lateral rail 29 of the partial rail 28 and the upper surface of the connecting shaft 52 .

(7) Electrical Configuration of Heat Treatment Apparatus 1 Next, the electrical configuration of the heat treatment apparatus 1 will be described with reference to the block diagram of FIG.

A control section 108 which is a control means of the heat treatment apparatus 1 is connected to an operation section 110 which comprises a computer and is used by an operator to operate the heat treatment apparatus 1 .

The control unit 108 is also connected to a drive motor 26 that rotates the drive sprocket 20, a driven slide motor 25, a drive slide motor 37, and a positioning motor 46 that moves the drive table 38 in the front-rear direction.

Each device in each heat treatment chamber 5 is connected to the controller 108 . That is, the pressure sensor 196, the upper temperature sensor 158, the lower temperature sensor 258, the upper left fan 172, the upper right fan 174, the upper left heater 184, the upper right heater 186, the lower temperature sensor 258, and the lower left fan in each heat treatment chamber 5 272, a lower right fan 274, a lower left heater 284, a lower right heater 286 are connected, and a pair of left and right connecting motors 70, 70 for rotating a pair of left and right male screw portions 68, an air supply inside the main air supply pipe 200 A damper 204 is connected.

An exhaust device 212 provided in the main exhaust pipe 206 is connected to the control unit 108 .

(8) Operating state of tenter device 10 Next, the operating state of the tenter device 10 will be described with reference to FIG.

As shown in FIG. 2, when the film F is carried in at a constant speed through the inlet, the pair of left and right clips 24, 24 grip both edges of the film F and run at a running speed V. As shown in FIG. The tenter device 10 runs inside a heat treatment device (not shown), and the film F is laterally stretched or obliquely stretched by the tenter device 10 while being heated. As shown in FIGS. 8 and 9, the clip 24 gripping the film F moves along the partial rail 28 of the tenter rail 16. As shown in FIGS. In this case, the first running wheel 100 of the clip 24 runs along the surface of the vertical rail 27 of the partial rail 28 and the surface of the guide plate 72, and the second running wheel 104 runs along the surface of the vertical rail 27 of the partial rail 28. Moving along the rear surface and the rear surface of the guide plate 72 , the third running wheel 106 moves on the horizontal rail 29 of the partial rail 28 and the upper surface of the connecting shaft 52 .

A case where the first running wheel 100 moves on the surface of the guide plate 72 will be described with reference to FIG. 13 .

The front spring plate 74 of the guide plate 72 is in a state in which the projecting piece 80 of the first front spring plate 74a and the concave portion 88 of the second front spring plate 74b are fitted. Therefore, as shown in FIG. 13, a gap 74c is formed between the first front spring plate 74a and the second front spring plate 74b. However, as shown in FIG. 13, the lower side of the projecting piece 80 and the lower side of the recess 82 are always continuous regardless of the gap 74c. Therefore, as shown in FIG. 13, the first running wheel 100 passes through the boundary between the protrusion 80 and the recess 82 at the position of the gap 74c. In this case, the first running wheel 100 does not pass through the holding plate 84 and the bolt 83 . As a result, the first running wheel 100 can smoothly pass through the surface of the vertical rail 27 of the partial rail 28, the first front spring plate 74a, the boundary, and the second front spring plate 74b.

A case where the second running wheel 104 moves on the back surface of the guide plate 72 will be described with reference to FIG. 14 .

The second running wheel 104 moves the rear surface of the vertical rail 27 of the partial rail 28, the first rear spring plate 76a, and the second rear spring plate 76b. In this case, a gap 76c is also generated between the first back spring plate 76a and the second back spring plate 76b, creating a step. However, even in this case, the second running wheel 104 passes through the boundary between the upper side of the projecting piece 86 of the first back spring plate 76a and the upper side of the concave portion 88 of the second back spring plate 76b, so that the second running wheel 104 can move smoothly without steps. can pass. Also, the second running wheel 104 does not pass through the position of the pressing plate 90 and the bolt 87 .

As the width of the pair of left and right tenter rails 16, 16 increases, the film F is laterally stretched or obliquely stretched to reach the outlet.

(9) Operating State of Heat Treatment Chamber 5 Next, the operating state of the heat treatment chamber 5 will be described with reference to FIGS. 3 to 5. FIG.

As described above, the film F supported by the pair of left and right partial rails 28, 28 of the tenter device 10 in a spread state passes through the conveying path between the upper nozzle 162 and the lower nozzle 262, and is subjected to heat treatment by being blown with hot air. done. The flow of hot air at this time will be described.

As shown in FIGS. 3 to 5, the air that has flowed in from the left air supply port 188 passes through the upper left heater 184, is heated, becomes hot air, and reaches the compartment 178. As shown in FIG.

The hot air is then blown by the upper left fan 172 in the compartment 178 and passes through the upper left filter 168 in the compartment 176 to remove dirt, dust, etc. from the incoming hot air and into the left side of the upper duct 160. Hot air is sent.

Air entering from the right air supply port 190 passes through the upper right heater 186 to be heated and reaches the compartment 182 .

The hot air is then blown by the upper right fan 174 in the compartment 182 and passes through the upper right filter 170 in the compartment 180 to the right side of the upper duct 160 .

The hot air blown from both the left and right sides passes through the upper duct 160 and is blown from the upper nozzles 162 onto the upper surface of the film F being conveyed.

The hot air bounced back from the upper surface of the film F flows upward from both left and right sides and is exhausted from a pair of left and right exhaust ports 192 and 194 .

Further, as shown in FIGS. 3 to 5, the air that has flowed in from the left air supply port 188 passes through the lower left heater 284, is heated, becomes hot air, and reaches the compartment 278. As shown in FIG.

The hot air is then blown by the lower left fan 272 in the compartment 278 and passes through the lower left filter 268 in the compartment 276 to remove dirt, dust, etc. from the incoming hot air and into the left side of the lower duct 260. Hot air is sent.

As shown in FIGS. 3-5, air entering from the right air inlet 190 passes through the lower right heater 286 and is heated to the compartment 282 .

The hot air is then blown by lower right fan 274 in compartment 282 and passes through lower right filter 270 in compartment 280 to the right side of lower duct 260 .

The hot air blown from both the left and right sides passes through the lower duct 260 and is blown from the plurality of lower nozzles 262 onto the lower surface of the film F being conveyed.

The hot air bounced back from the lower surface of the film F flows downward from both left and right sides and is exhausted from a pair of left and right exhaust ports 192 and 194 .

The hot air blown as described above is exhausted from the pair of left and right exhaust ports 192 and 194 and flows into the main exhaust pipe 206 from the pair of left and right exhaust connecting pipes. At this time, the hot air exhausted by the exhaust device 212 is forcibly exhausted to the outside.

When the hot air is blown onto the film F as described above, if the upper detected temperature measured by the upper temperature sensor 158 is lower than the reference temperature, the upper left heater 184 and the upper right heater 186 are heated further, The temperature of the hot air blown from both sides can be raised, and the hot air at the reference temperature can be blown onto the film F. Conversely, when the temperature detected by the upper temperature sensor 158 becomes higher than the reference temperature, the heating of the upper left heater 184 and the upper right heater 186 is suppressed.

Similarly, in the lower temperature sensor 258 provided in the lower nozzle 262, when the lower detected temperature is lower than the reference temperature, the lower left heater 284 and the lower right heater 286 heat it. Heating of the heater 284 and the lower right heater 286 is suppressed. As a result, hot air can be blown onto the film F from above and below at a desired temperature.

Since the pressure inside the heat treatment chamber 5 changes due to the blown hot air, the pressure sensor 196 detects this pressure. When the pressure detected by the pressure sensor 196 is higher than the reference pressure, the air supply damper 204 is closed from the current state to reduce the amount of air supplied, and the amount of air exhausted from the pair of left and right exhaust ports 192 and 194 is reduced. Do not change about . As a result, the inflowing air is reduced, so that the pressure in the heat treatment chamber 5 is lowered and reaches the reference pressure.

On the other hand, when the pressure detected by the pressure sensor 196 is lower than the reference pressure, the air supply damper 204 is opened more than the current state to increase the amount of air supplied from the pair of left and right air supply ports 188 and 190 . On the other hand, the amount of air exhausted from the pair of left and right exhaust ports 192 and 194 is kept constant. As a result, the amount of air supplied increases, and the pressure inside the heat treatment chamber 5 rises and reaches the reference pressure.

Further, hot air is blown onto the upper surface of the film F from both the left and right sides by the left and right upper left fan 172 and the upper right fan 174, so that the hot air can be evenly blown along the width direction of the film F. The lower left fan 272 and the lower right fan 274 can evenly blow hot air in the width direction on the lower surface of the film F as well.

Further, the upper left fan 172, the upper right fan 174, the upper left heater 184, the upper right heater 186, the upper left filter 168, and the upper right filter 170 are provided in spaces separated by compartments 176, 178, 180, 182, respectively. Therefore, the hot air reaching the upper duct 160 does not flow backward or mix.

A lower left fan 272, a lower right fan 274, a lower left heater 284, a lower right heater 286, a lower left filter 268, and a lower right filter 270 are also provided in each space partitioned by compartments 276, 278, 280, 282. Therefore, the hot air up to the lower duct 260 does not flow backward or mix.

Since the connecting portion 4 of the partial rails 28, 28 is supported by the tenter support base 214 provided from the bottom surface of the heat treatment chamber 5, the clip 24 can be stably run while maintaining a horizontal state, and the connecting portion 4 can be connected. The table 56 can be moved in the horizontal direction.

(10) Effect According to the present embodiment, the hot air above the film F is blown from the upper left fan 172 and the upper right fan 174, so that the hot air is evenly blown across the film F in the width direction. Further, since the temperature of the hot air is adjusted on both the left and right sides by the upper left heater 184 and the upper right heater 186, the temperature of the hot air can be made uniform in the width direction. The same applies to the lower surface of the film F as well.

Further, when the pressure in the heat treatment chamber 5 rises, the air supply damper 204 is closed from the current state to reduce the amount of air supply, and the exhaust amount is maintained as it is to easily lower the pressure. be able to. Conversely, when the pressure in the heat treatment chamber 5 is low, the pressure can be easily increased by opening the air supply damper 204 to increase the amount of air supply and maintain the exhaust amount. .

Further, since the connection portion 4 of the pair of left and right partial rails 28, 28 of the tenter device 10 is supported by the tenter support base 214 installed from the bottom surface of the heat treatment chamber 5, the pair of left and right clips 24, 24 can be stably attached. Since it can be made to run, the film F supported by the pair of left and right clips 24, 24 can also be stably transported without shifting its posture, and the hot air blown from the upper nozzle 162 and the lower nozzle 262 hits it evenly in the width direction. . Moreover, the connecting base 56 can be stably moved in the left-right direction.

In addition, the position where the tenter support 214 is provided is such that the lower duct 260 is slightly shorter than the upper duct 160 and is provided in the vicinity of the carry-out port. . In particular, since the upper duct 160 and the upper nozzle 162 are also provided above the tenter support 214 and the hot air hits the film F, the heat treatment can be performed. Further, since the tenter support 214 is provided near the carry-out port, even if the connecting portion 4 above the tenter support 214 breaks down, it can be easily repaired from the carry-out port side.

Change example

In the above embodiment, the tenter support 214 is provided near the carry-out port of the heat treatment chamber 5 . may be set to Also at this time, the upper duct 160 and the upper nozzle 162 are provided above the tenter support 214 .

In the above-described embodiment, one upper temperature sensor 158 and one lower temperature sensor 258 are provided inside the upper nozzle 162 and the lower nozzle 262. Instead of this, a pair of left and right upper temperature sensors 158 are provided. A pair of left and right lower temperature sensors 258 may be provided inside the lower nozzle 262 to control the lower left heater 284 and the lower right heater 286, respectively. This makes it possible to more accurately control the temperature of the hot air blown from the top, bottom, left and right.

In the above embodiment, the clip tenter device has been described, but instead of this, a pin tenter device may be used to adapt the present embodiment.

While one embodiment of the invention has been described above, this embodiment is provided by way of example and is not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 1... Heat treatment apparatus, 4... Connection part, 5... Heat treatment chamber, 10... Tenter device, 16... Tenter rail, 18... Driven sprocket, 20... Drive sprocket, 22 ... tenter chain, 24 ... clip, 26 ... drive motor, 28 ... partial rail, 30 ... driven base, 38 ... drive base, 172 ... upper left fan, 174. Upper right fan 184 Upper left heater 186 Upper right heater 272 Lower left fan 274 Lower right fan 284 Lower left heater 286 Lower right heater, 214 ... tenter support

Claims (8)

A pair of left and right tenter rails,
a pair of left and right endless tenter chains arranged along the pair of left and right tenter rails;
Chain driving means for moving the pair of left and right tenter chains in the front-rear direction;
The web is supported from both left and right sides, respectively, is provided on the pair of left and right tenter chains at predetermined intervals, and travels along the pair of left and right tenter rails by moving the pair of left and right tenter chains, a plurality of pairs of left and right support means for transporting the web from front to back;
a tenter apparatus having
one or a plurality of heat treatment chambers for heat-treating the web conveyed in the front-rear direction, in which the pair of left and right tenter rails are housed;
has
The heat treatment chamber is
an upper duct provided along the front-rear direction above the conveying path of the web;
upper nozzles provided at predetermined intervals in the lower part of the upper duct for blowing hot air onto the web from above;
a lower duct provided along the front-rear direction below the transport path;
lower nozzles provided at predetermined intervals above the lower duct for blowing hot air onto the web from below;
an upper left fan that supplies hot air to the left side in the upper duct;
an upper right fan that supplies hot air to the right side in the upper duct;
a lower left fan that supplies hot air to the left side in the lower duct;
a lower right fan that supplies hot air to the right side in the lower duct;
a tenter support portion provided between the lower duct in the heat treatment chamber and a loading portion or unloading portion of the web in the heat treatment chamber for supporting the pair of left and right tenter rails;
has
The pair of left and right tenter rails are
a plurality of pairs of left and right partial rails;
connecting movement means for moving the connecting portion of the adjacent partial rails in the front-rear direction and the left-right direction;
has
The connecting moving means is supported by the tenter support,
Heat treatment equipment. A pair of left and right air supply units are provided on the ceiling surface of the heat treatment chamber,
A pair of left and right exhaust units are provided on the ceiling surface,
The heat treatment apparatus according to claim 1. when the pressure in the heat treatment chamber is higher than the reference pressure, reducing the amount of air supplied from the air supply unit and maintaining the amount of exhaust from the exhaust unit;
when the pressure in the heat treatment chamber is lower than the reference pressure, increasing the amount of air supplied from the air supply unit and maintaining the amount of exhaust from the exhaust unit;
The heat treatment apparatus according to claim 2 . The upper duct is longer than the lower duct, and the upper duct and the upper nozzle are provided above the tenter support,
The heat treatment apparatus according to claim 1 . The connecting moving means is
a connecting base provided on the upper part of the tenter support;
a connecting shaft that rotatably connects the ends of the adjacent partial rails;
a long hole provided in the connecting base in the front-rear direction and engaged with the connecting shaft;
a connecting base moving means for moving the connecting base in the lateral direction with respect to the tenter support;
The heat treatment apparatus according to claim 1 , comprising: The connecting base moving means is
a support rail provided in the left-right direction on the upper part of the tenter support;
a wheel provided on the connecting base for moving the support rail;
a female thread provided at the bottom of the connecting base;
a male threaded portion screwed into the female threaded portion;
a screw rotating means for rotating the male screw portion;
The heat treatment apparatus according to claim 5 , comprising: the support means is a clip or a pin;
The heat treatment apparatus according to claim 1. A pair of left and right tenter rails,
a pair of left and right endless tenter chains arranged along the pair of left and right tenter rails;
Chain driving means for moving the pair of left and right tenter chains in the front-rear direction;
The web is supported from both left and right sides, respectively, is provided on the pair of left and right tenter chains at predetermined intervals, and travels along the pair of left and right tenter rails by moving the pair of left and right tenter chains, a plurality of pairs of left and right support means for transporting the web from front to back;
one or a plurality of heat treatment chambers for heat-treating the web conveyed in the front-rear direction, in which the pair of left and right tenter rails are housed;
has
The heat treatment chamber is
an upper duct provided along the front-rear direction above the conveying path of the web;
upper nozzles provided at predetermined intervals in the lower part of the upper duct for blowing hot air onto the web from above;
a lower duct provided along the front-rear direction below the transport path;
lower nozzles provided at predetermined intervals above the lower duct for blowing hot air onto the web from below;
a tenter supporting portion for supporting the pair of left and right tenter rails is provided between the lower duct in the heat treatment chamber and a portion of the web carried in or out of the heat treatment chamber;
The pair of left and right tenter rails are
a plurality of pairs of left and right partial rails;
connecting movement means for moving the connecting portion of the adjacent partial rails in the front-rear direction and the left-right direction;
has
The connecting moving means is supported by the tenter support,
Heat treatment equipment.

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