The present invention relates to a paint baking oven and a paint baking method.
For the purposes of productivity improvement and adjustability of body color in a coating process line for vehicle bodies, various processes are performed, such as processes for an electrodeposition coat (under coat), intermediate coat and topcoat and antirust treatment, in a state in which lid parts such as doors and hoods are attached to main shell bodies. In the processes for an intermediate coat and topcoat, the vehicle body as an object to be coated is placed on a transfer trolley, applied with paint while being conveyed in a paint coating booth, and carried into a paint baking oven for baking of a wet coating film. The paint baking oven used in the coating process line is configured such that a tunnel-shaped oven body is provided with an air supply duct for hot air and the hot air is blown to the whole vehicle body, which is being conveyed in the oven body, to bake the wet coating film (See JP2004-50021A).
A baking curable-type paint is used for vehicle bodies. The quality assurance standard for the cured coating film is, for example, holding of 140° C.×20 minutes for an intermediate paint and topcoat paint. In the conventional paint baking oven, however, the hot air is less likely to go around into narrow portions, such as those around hinges of doors, because of the structure of the vehicle body as compared with the body exterior parts to which the hot air is easy to blow. Thus, unfortunately, the narrow portions cannot readily satisfy the above-described quality assurance standard, such as holding of 140° C.×20 minutes.
A problem to be solved by the present invention is to provide a paint baking oven and paint baking method that are able to satisfy the baking condition for a wet coating film across the whole vehicle body.
The present invention solves the above problem by providing a paint baking oven that bakes a wet coating film applied to a vehicle body while conveying the vehicle body. The vehicle body has a main shell body to which side doors are attached via hinges. The paint baking oven has an oven body that is composed of a first oven body and a second oven body. The first oven body has a side-to-side width corresponding to a body width of the vehicle body in a state of closing the side doors. The second oven body has a width wider than the side-to-side width of the first oven body. The width of the second oven body corresponds to a body width of the vehicle body in a state of opening the side doors.
According to the present invention, the side doors are opened in the second oven body and in this state the hot air can be blown toward the wet coating films applied to the main shell body and side doors in the vicinities of hinges thereby to satisfy a predetermined baking condition. Moreover, since the first oven body has a side-to-side width corresponding to the body width of the vehicle body in a state of closing the side doors and this side-to-side width is narrower than that of the second oven body, it is possible to avoid unnecessary volume increase of the oven as a whole and suppress needless deterioration of the heat efficiency.
Hereinafter, best modes for carrying out the present invention will be described with reference to one or more embodiments in which the paint baking oven and paint baking method of the present invention are applied to a topcoat paint baking oven 1, but the paint baking oven and paint baking method of the present invention can also be applied to an intermediate paint baking oven and an under paint baking oven (electrodeposition paint baking oven), or to an intermediate paint and topcoat paint baking oven which will be described later, other than the topcoat paint baking oven.
The topcoat paint baking oven 1 according to one or more embodiments of the present invention is one of devices that constitute a coating process line PL. The topcoat paint baking oven 1 is a device for baking a top coating film, which is applied to a shell body B (referred also to as a “vehicle body B”) loaded on a transfer trolley 50, while conveying the shell body B. In the following description, the overview of a production line and the coating process line PL for vehicles will first be described and the vehicle body B and the topcoat paint baking oven 1 will then be described in detail.
The production line for vehicles is composed mainly of four lines: a press-forming process line PRL; a shell body assembly process line (referred also to as a “welding process line”) WL; a coating process line PL; and a vehicle component assembly process line (referred also to as an “outfitting process line”) ASL. In the press-forming process line PRL, various panels that constitute a vehicle body B are press-formed and each conveyed in a state of a single pressed component to the shell body assembly process line WL. In the shell body assembly process line WL, subassemblies are assembled for respective sites of the vehicle body, such as a front body, center floor body, rear floor body and side bodies, and welding is performed for predetermined parts of the assembled front body, center floor body and rear floor body to assemble an under body, to which the side bodies and a roof panel are welded to assemble a main shell body B1 (which refers to a shell body excluding lid parts). Finally, preassembled lid parts such as a hood F, side doors D1 and D2 and trunk lid T (or back door) are attached to the main shell body B1 via hinges H (which will be described later with reference to
General configuration of the coating process line PL will then be described.
The coating process line PL of the embodiment illustrated in
As illustrated in
Although not illustrated, the pretreatment process for electrodeposition coat P11 comprises a degreasing process, water-washing process, surface conditioning process, chemical conversion film forming process, water-washing process, and water-draining process. In the press-forming process line PRL and the shell body assembly process line WL, press oil and dust such as iron powder due to welding are attached to the vehicle body B. When the vehicle body B is carried into the coating process line PL, therefore, the degreasing process and the water-washing process are used to wash and remove such oil and dust. In the surface conditioning process, surface conditioner components are adsorbed to the surface of the vehicle body B thereby to increase the number of reaction starting points in the subsequent chemical conversion film forming process. The adsorbed surface conditioner components act as nuclei of coating film crystals to accelerate the film forming reaction. In the chemical conversion film forming process, the vehicle body B is immersed in a chemical conversion treatment liquid, such as zinc phosphate solution, to form a chemical conversion film on the surface of the vehicle body B. In the water-washing process and the water-draining process, the vehicle body B is washed with water and then dried.
In the electrodeposition paint coating process P12, the vehicle bodies B pretreated in the pretreatment process for electrodeposition coat P11 are successively conveyed by an overhead conveyor with a predetermined pitch at a predetermined conveying speed. Each vehicle body B is then immersed in a boat-shaped electrodeposition bath that is filled with an electrodeposition paint and a high voltage is applied between a plurality of electrode plates provided in the electrodeposition bath and the vehicle body B (specifically a hanger having electrical conductivity). This allows the surface of the vehicle body B to be formed with an electrodeposition coating film owing to the electrophoretic action of the electrodeposition paint. Examples of the electrodeposition paint include a thermoset paint of which the primary resin is an epoxy-based resin such as polyamine resin. For the antirust property, it is preferred to use a cation-type electrodeposition paint as the electrodeposition paint, in which case a high voltage for the positive electrode is applied to the side of the electrodeposition paint, but an anion-type electrodeposition paint may also be used. When the anion-type electrodeposition paint is used, a high voltage for the positive electrode is applied to the side of the vehicle body B.
After exiting the electrodeposition bath of the electrodeposition paint coating process P12, the vehicle body B is conveyed to a water-washing process in which the electrodeposition paint attached to the vehicle body B is washed away using industrial water and/or pure water. During this operation, the electrodeposition paint carried out of the electrodeposition bath is recovered in the water-washing process. At the stage completed with the water-washing process, an unbaked electrodeposition coating film having a thickness of about 10 to 35 μm is formed on the surface of the vehicle body B and in the hollow structure parts of the vehicle body B. After completion of the electrodeposition paint coating process P12, the vehicle body B loaded on a hanger is transferred to a transfer trolley 50 (which will be described later with reference to
In the electrodeposition paint baking process P13, the vehicle bodes B loaded on transfer trolleys are successively conveyed by a floor conveyor with a predetermined pitch at a predetermined conveying speed. Then, for each vehicle body B, baking is performed by maintaining a temperature of 160° C. to 180° C. for 15 to 30 minutes, for example, and a baked electrodeposition coating film having a thickness of 10 to 35 μm is thereby formed on the interior and exterior of the vehicle body B and in the hollow structure parts of the vehicle body B. From the electrodeposition paint baking process P13 to the final inspection process P6, transfer trolleys 50 loaded with vehicle bodies B are successively conveyed using a floor conveyor, but the conveying pitch and conveying speed of the transfer trolleys 50 in each process are appropriately set for the process. The floor conveyor is therefore composed of a plurality of conveyors and the conveying pitch and conveying speed in each process are set as predetermined values.
In the present description and scope of claims, the “paint” such as an electrodeposition paint, intermediate paint and topcoat paint refers to a liquid state before being applied to an object to be coated while the “coating film” such as an electrodeposition coating film, intermediate coating film and top coating film refers to a film-like, unbaked (wet) or baked state after being applied to an object to be coated, and both are thus distinguished. In the present description and scope of claims, the upstream side and the downstream side mean those with reference to the conveying direction of the vehicle body B as an object to be coated. In the present description, conveying the vehicle body B forward means conveying the vehicle body B along the longitudinal direction axis of the vehicle body in a state in which the vehicle front part of the vehicle body B is positioned at the front side in the conveying direction and the vehicle rear part is positioned at the rear side, while conveying the vehicle body B backward means conveying the vehicle body B along the longitudinal direction axis of the vehicle body, conversely, in a state in which the vehicle rear part of the vehicle body B is positioned at the front side in the conveying direction and the vehicle front part is positioned at the rear side. In the under coating process P1 to the final inspection process P6 according to one or more embodiments of the present invention, the vehicle body B may be conveyed forward or may also be conveyed backward.
In the sealing process P2 (which includes a floor back coating process and a stone-guard coating process), the vehicle body B formed with the electrodeposition coating film is conveyed and a sealing material of vinyl chloride-based resin is applied to joining parts of steel panels and edge parts of steel panels for the purpose of antirust or sealing. In the floor back coating process, a vinyl chloride resin-based anti-flipped stone material is applied to wheel housings and a floor back of the vehicle body B. In the stone-guard coating process, an anti-flipped stone material of polyester-based resin or polyurethane-based resin is applied to lower portions of the body exterior, such as side sill panels, fender panels and doors. These sealing material and anti-flipped stone material are to be cured in a dedicated baking process or in the intermediate paint baking process P32 which will be described below.
The intermediate coating process P3 of the coating process line PL of
In the intermediate paint baking process P32 of the coating process line PL of
In the wet sanding process P4 of the coating process line PL of
The topcoat process P5 of the coating process line PL of
Each of the topcoat base paint and the topcoat clear paint is a paint of which the primary resin is an appropriate resin, such as acrylic resin, alkyd resin and polyester resin, and may be any of an aqueous paint and organic solvent-based paint. In consideration of the finishing property such as orientation of bright pigment, the topcoat base paint is diluted to about 80% as the weight ratio for coating (solid content is about 20% to 40%) while the topcoat clear paint is diluted to about 30% as the weight ratio for coating (solid content is about 70% to 80%). In general, however, the applied solid content of the topcoat base paint will increase to 70% or more in a flash-off process (setting process in which the solvent naturally evaporates in the booth) after the application.
The exterior body color of the vehicle body B according to one or more embodiments of the present invention is a metallic-type body color that contains various bright pigments such as aluminum and mica, so the topcoat base paint and the topcoat clear paint are applied to the vehicle body B, but the present invention is not limited to this. For example, the exterior body color of the vehicle body B may be a solid-type body color. The solid-type body color is a coating color that does not contain a bright pigment. In this case, the topcoat base paint is not applied and a topcoat solid paint is applied as substitute for the topcoat clear paint. Examples of such a topcoat solid paint include paints of which the primary resin is the same as that of the topcoat base paint and the topcoat clear paint.
In the topcoat paint baking process P52 according to one or more embodiments of the present invention, the vehicle body B to which the topcoat paint is applied in the topcoat paint coating booth is conveyed to the topcoat paint baking oven 1. In the topcoat paint baking process P52, the vehicle body B is passed through the topcoat paint baking oven 1 under a predetermined condition thereby to form a baked top coating film. Specific configuration of the topcoat paint baking oven 1 and topcoat paint baking process P52 according to one or more embodiments of the present invention will be described later.
The thickness of the topcoat base coating film is, for example, 10 to 20 μm and the thickness of the topcoat clear coating film is, for example, 15 to 30 μm. When the exterior body color is a solid-type body color, the thickness of the topcoat solid coating film is, for example, 15 to 35 μm. Finally, the vehicle body completed with all the above processes (vehicle body finished with coating) is conveyed to the final inspection process P6 in which various tests are performed for evaluation of properties, such as appearance and image sharpness of the coating film.
On the other hand, the coating process line PL illustrated in
In the intermediate paint and topcoat paint coating process P71 of the coating process line PL illustrated in
Next, an example of the vehicle body B applied to the coating process line PL according to one or more embodiments of the present invention will be described with reference to
As illustrated in
The vehicle body B according to one or more embodiments of the present invention is the vehicle type of a four-door sedan, as illustrated, and the side doors D at each side are therefore provided as a front door D1 and a rear door D2. In the case of a two-door sedan or a two-door coupe, each side has a front door D1 and a front door opening part B2 and does not have a rear door D2 and a rear door opening part B3. In one or more embodiments of the present invention, the front door D1 is arranged to correspond to the front door opening part B2 and the rear door D2 is arranged to correspond to the rear door opening part B3. In this case, the side doors D, which include the front doors D1 and the rear doors D2, correspond to an example of the side doors according to the present invention. In the cases of the above-described two-door sedan and two-door coupe, the front doors D1 correspond to an example of the side doors according to the present invention.
As illustrated in
As illustrated in
In the shell body assembly process line WL, a subassembly of each hinge H1 is preliminarily assembled such that the hinge pin H13 is inserted in four holes of the two hinge brackets H11 and H12 and fixed by means of swaging or press fitting, and the subassembly is carried into the final process. Before the front door D1 is attached to the main shell body B1, one hinge bracket H11 of the subassembly of each hinge H1 is bolted to the front door D1, which is then positioned with respect to the front door opening part B2 of the main shell body B1 using a jig and the like, and the other hinge bracket H12 is bolted to the front pillar B4. This allows the front door D1 to move pivotally about the hinge pins H13 and the front door D1 can thus be opened and closed.
Similarly, the hinge H2 has two hinge brackets H21 and H22 and a hinge pin H23 as denoted by reference numerals in parentheses of
As illustrated in
Referring again to
Next, the topcoat paint baking oven 1 according to one or more embodiments of the present invention will be described.
As illustrated in
The floor surface 16 of the raised-floor portion 12 of the oven body 10 has approximately the same height as that of an opening upper end edge of the entrance of the oven body 10 and that of an opening upper end edge of the exit of the oven body 10. Owing to this structure, the hot air supplied into the raised-floor portion 12 can be suppressed from escaping to external of the oven body 10 via the entrance or exit. On the floor surface 16 of the oven body 10, the conveyor 40 is laid along the extending direction of the oven body 10. The conveyor 40 conveys the transfer trolleys 50 on which the vehicle bodies B are loaded.
The hot air supply device 20 is equipment for supplying the generated hot air into the raised-floor portion 12 of the oven body 10 and, as illustrated in
As illustrated in
As illustrated in
As illustrated in the plan view of
The raised-floor portion 12 according to one or more embodiments of the present invention constitutes a substantial heating region. As illustrated in
As illustrated in
Thus, the second hot air blowoff ports 26 are opened toward the upstream side. In the second oven body 122, therefore, the hot air can readily be blown toward the vicinities of the hinges H of the vehicle body B which is conveyed in a state in which the side doors D are opened. In addition, since the second hot air blowoff ports 26 are provided at the upper parts and lower parts of the side wall surfaces 15 and 15, the hot air from the second hot air blowoff ports 26 provided at the upper parts is blown mainly to the upper side of the vicinities of the hinges H while the hot air from the second hot air blowoff ports 26 provided at the lower parts is blown mainly to the lower side of the vicinities of the hinges H. The coated surfaces of the narrow portions N1 and N2 in the vicinities of the hinges H can thereby be uniformly baked.
The second oven body 122 of the raised-floor portion 12 acts also as the temperature rising region of the oven body 10 and it is therefore preferred to provide the first hot air blowoff ports 25 at respective air supply ducts 24 and 24 of the ceiling surface 14 and side wall surfaces 15. With regard to the first hot air blowoff ports 25 provided at the air supply ducts 24 of the side wall surfaces 15, it is preferred to form the guide parts with a blowing angle such that, as illustrated by blank arrows of
In contrast, the first oven body 121 is preferably provided only with the first hot air blowoff ports 25, as illustrated in
Although not particularly limited, in the first oven body 121 and the second oven body 122, the heat quantity of the hot air blown from the second hot air blowoff ports 26 is preferably set larger than the heat quantity of the hot air blown from the first hot air blowoff ports 25. In one or more embodiments of the present invention, the wind speed of the hot air blown from the second hot air blowoff ports 26 is made larger than the wind speed of the hot air blown from the first hot air blowoff ports 25 thereby to set larger the heat quantity of the hot air blown from the second hot air blowoff ports 26. Specifically, it is preferred that the wind speed of the hot air blown from the first hot air blowoff ports 25 illustrated in
The air exhauster 30 is equipment for exhausting the evaporated solvent in the oven body 10 to external of the system, as illustrated in
Next, a door open/close keeping member 60 and a door open/close mechanism 70 will be described as an example. The door open/close keeping member 60 is configured to maintain the side doors D1 and D2 in a state of being closed in the upward slope portion 11 at the entrance side, maintain the side doors D1 and D2 in a state of being opened in the second oven body 122, and maintain the side doors D1 and D2 again in a state of being closed in the first oven body 121. The door open/close mechanism 70 is configured to open and close the side doors D1 and D2 using the door open/close keeping member 60.
As illustrated in
The fixing frame 61 attached to a door is composed of a round rod or pipe made of metal and has a base end part 612 and a tip end part 611. The base end part 612 is fixed to the joint part 64, which will be described later, by means of welding, swaging, or the like. The tip end part 611 is folded into a predetermined shape so as to be capable of engaging with a working opening D11 of the inner panel of a side door D1. The operation rod 63 is fixed to the fixing frame 61 by welding or the like and extends to the window opening part of the side door D. The operation rod 63 is provided for operating the door open/close keeping member 60 using a door open/close mechanism 70 which will be described later.
The fixing frame 62 attached to a body is configured to include a frame 621, rotative body 622, and rotation-regulated body 623. The frame 621 is composed of a round rod or pipe made of metal and has a base end and a tip end. The base end is fixed to the joint part 64, which will be described later, by means of welding, swaging, or the like. The tip end is attached to the rotative body 622. The rotative body 622, which supports the frame 621, has a lower end that is inserted in a hole formed at the inner panel of a side sill B9. The rotation-regulated body 623, which supports the rotative body 622 in a rotatable manner, is placed on the side sill B9 of the door opening part B2. That is, as illustrated in
As illustrated in
Hereinafter, the direction of rotation of the rotative part 642 illustrated in
The fixed part 641 is provided with a pair of approximately circular shaft bush plates 641a and 641a that face each other to have a certain space while the rotative part 642 is provided with a pair of ratchet plates 642a and 642a that face each other to have a certain space. Outer edge parts of the ratchet plates 642a and 642a are each formed with a plurality (two in this example) of ratchet teeth 642b that are arranged side by side at a predetermined pitch. These ratchet teeth 642b are formed to have a certain pitch that allows the rotative part 642 to be engaged with the reverse rotation regulating latch 644 so that the opening angle θ of the rotative part 642 to the fixed part 641 can take the plurality of angle positions between the angle in a state of closing the side door D and the angle in a state of opening the side door D. In one or more embodiments of the present invention, the number of ratchet teeth 642b at each side, that is, the number of steps to which the opening angle θ of the rotative part 642 (opening angle of the side door D) can be adjusted, is not particularly limited. For example, one or more steps may be provided between the adjacent steps.
The rotative part 642 is provided integrally with a first abutting part 642c and a second abutting part 642d that come into contact with a first projecting part 643a and second projecting part 643b of the cam plate 643, respectively. The first abutting part 642c and the second abutting part 642d are provided at both the upper and lower end parts of the rotative part 642 between the ratchet plates 642a and 642a. As illustrated in
The reverse rotation regulating latch 644, which regulates the reverse rotation of the rotative part 642 (direction of opening the side door D), is disposed between the shaft bush plates 641a and 641a of the fixed part 641 and, in this state, the pivot shaft 646 composed of a rivet is inserted in shaft holes provided in the shaft bush plates 641a and 641a and a shaft hole provided in the reverse rotation regulating latch 644 and is fixed thereto so as not to drop off. This allows the reverse rotation regulating latch 644 to be pivotably supported by the pivot shaft 646 relative to the fixed part 641. The tip end of the reverse rotation regulating latch 644 is formed with two latch pieces 644a and 644a that can engage with the ratchet teeth 642b of the ratchet plates 642a and 642a. The reverse rotation regulating latch 644 is rotationally biased by the torsion coil spring 647 attached to the pivot shaft 646 in the clockwise direction, that is, the direction of engaging with the ratchet teeth 642b and 642b.
When the reverse rotation regulating latch 644 pivots about the pivot shaft 646 in the clockwise direction of
As illustrated in
In the joint part 64 configured as the above, in a state in which the rotative part 642 is opened with respect to the fixed part 641 as illustrated in
In the joint part 64 according to one or more embodiments of the present invention, an operation to cancel the regulation of rotation of the rotative part 642 in the negative rotation direction L (direction of opening the side door D), that is, a regulation cancel operation for reverse rotation, is performed in the following manner. First, the rotative part 642 is rotated largely in the positive direction (direction of closing the side door D) until the opening angle θ of the rotative part 642 becomes less than a predetermined regulation cancel angle. On the way of this positive rotation operation, the first abutting part 642c of the rotative part 642 comes into contact with the first projecting part 643a of the cam plate 643 to rotate the cam plate 643 together with the rotative part 642 in the positive direction. In accordance with this positive rotation operation, the latch pieces 644a of the reverse rotation regulating latch 644 are pressed against the biasing force of the torsion coil spring 647 in the release direction along the guide part 643e of the cam plate 643 thereby to come to a state of running on the edge projecting part 643d. Thus, a state is maintained in which the engagement of the latch pieces 644a with the ratchet teeth 642b is released, that is, a state is maintained in which the regulation of rotation of the rotative part 642 in the negative rotation direction L (direction of opening the side door D) is canceled. This state therefore allows the rotation of the rotative part 642 in the negative rotation direction L. Then, when the rotative part 642 is rotated in the negative direction while the regulation of rotation of the rotative part 642 in the negative rotation direction L is canceled, the second abutting part 642d of the rotative part 642 comes into contact with the second projecting part 643b of the cam plate 643 to rotate the cam plate 643 together with the rotative part 642 in the negative direction. When the rotative part 642 is rotated until the opening angle θ comes to the maximum opening angle, the second abutting part 642d of the rotative part 642 presses the second projecting part 643b of the cam plate 643 to rotate the cam plate 643 in the negative direction. Through this operation, the latch pieces 644a of the reverse rotation regulating latch 644 pass from the edge projecting part 643d of the cam plate 643 across the guide part 643e to be located inside the edge recessed part 643c. This allows the latch pieces 644a to engage with the ratchet teeth 642b thereby to regulate the rotation of the rotative part 642 in the negative rotation direction L (direction of opening the side door D).
In short, in the second oven body 122 illustrated in
To perform such opening operation and closing operation for the side doors D1 and D2, as illustrated in
As illustrated in
On the other hand, each door close mechanism 72 is configured to include, as denoted by reference numerals in parentheses in
The topcoat paint baking oven 1 and topcoat paint baking method according to one or more embodiments of the present invention has the following actions and effects:
In most cases, a vehicle body B is configured to include a site that is easily exposed to hot wind and a site that is not easily exposed to hot wind. For example, even when vehicle bodies are conveyed into the topcoat paint baking oven 1 in a state of closing the side doors D, the hot air is less likely to go around into the narrow portions N1 and N2 in the vicinities of the hinges H1 and H2 of the side doors D. In contrast, the body exterior parts such as outer panels of the side doors D can be directly blown with the hot air and thus easily heated. For these reasons, if the setting condition for the hot air temperature, time of passage and the like in the topcoat paint baking oven 1 is adapted to the narrow portions N1 and N2 which cannot be easily heated, not only the body exterior parts which can be easily heated will be beyond the quality assurance standard to a large degree to needlessly consume energy, but also over-baking may possibly occur in some cases to rather deteriorate the coating quality. If, on the other hand, the setting condition for the hot air temperature, time of passage and the like in the topcoat paint baking oven 1 is adapted to the body exterior parts which can be easily heated, the baking condition for the coating films of the narrow portions N1 and N2 will not satisfy the quality assurance standard to cause so-called poor baking, and the deterioration in the coating film properties and delamination of the coating film may possibly occur. According to one or more embodiments of the present invention, in the second oven body 122 in which the vehicle bodies are conveyed in a state of opening the side doors D, the hot air is blown locally toward the coated surfaces of the narrow portions N1 and N2 which are relatively difficult to be heated, thereby to allow the baking condition to be uniform across the whole area of the coating film of the vehicle body B, and not only the coating film quality is improved but also energy saving can be achieved. Moreover, the first oven body 121 has a narrow oven width and the total space for the oven body 10 can thereby be minimized.
(2) According to one or more embodiments of the present invention as illustrated in
(3) According to one or more embodiments of the present invention as illustrated in
(4) According to one or more embodiments of the present invention as illustrated in
The above hot air supply device 20 corresponds to the hot air supplier of the present invention, the above first hot air blowoff ports 25 correspond to the body exterior part blowoff port of the present invention, and the second hot air blowoff ports 26 correspond to the spot blowoff port of the present invention.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/051994 | 1/26/2015 | WO | 00 |