JP5606578B2 - Reinforcing method and reinforcing device - Google Patents
Reinforcing method and reinforcing device Download PDFInfo
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- JP5606578B2 JP5606578B2 JP2013083903A JP2013083903A JP5606578B2 JP 5606578 B2 JP5606578 B2 JP 5606578B2 JP 2013083903 A JP2013083903 A JP 2013083903A JP 2013083903 A JP2013083903 A JP 2013083903A JP 5606578 B2 JP5606578 B2 JP 5606578B2
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Description
本発明は、補強方法及び補強装置に関する。 The present invention relates to a reinforcing method and a reinforcing device.
自動車のフェンダー、ルーフ等の自動車用外装部品は、一般に、鉄鋼等の金属板で形成されている。前記金属板は、燃費向上、生産コスト低減のために、肉薄に形成されて軽量化することが検討されている。 Automotive exterior parts such as automobile fenders and roofs are generally formed of a metal plate such as steel. In order to improve the fuel efficiency and reduce the production cost, it is considered that the metal plate is formed thin and light.
しかし、前記金属板を肉薄にすると所要の剛性を得られないことがあるので、該金属板の片面に樹脂製のリブ材を補強部材として設けた複合構造体とすることにより剛性を確保することが考えられる。前記金属板の補強方法としては、従来、加熱装置で加熱した金属板を搬送ロボットでリブ成形押圧装置へ搬送し、該リブ成形押圧装置において、溶融樹脂を吐出してリブ材に成形し、該リブ材を該金属板の表面に押圧ローラで押圧して前記複合構造体を形成する方法が知られている(例えば特許文献1参照)。 However, if the metal plate is made thin, the required rigidity may not be obtained. Therefore, the rigidity is ensured by using a composite structure in which a resin rib material is provided as a reinforcing member on one side of the metal plate. Can be considered. As a method for reinforcing the metal plate, conventionally, a metal plate heated by a heating device is transported to a rib forming pressing device by a transport robot, and in the rib forming pressing device, molten resin is discharged to form a rib material, A method of forming the composite structure by pressing a rib material against the surface of the metal plate with a pressing roller is known (see, for example, Patent Document 1).
しかしながら、従来の補強方法は、溶融樹脂から成形した前記リブ材を前記押圧ローラで前記金属板に押圧して前記複合構造体を形成するために、該リブ材の形状によっては該リブ材の成形機構が複雑になるとともに、該リブ材を冷却して固化する必要があり該複合体の形成速度が低くなるという不都合がある。また、従来の補強方法は、加熱された前記金属板の温度が前記搬送ロボットによる搬送中に低下し、前記リブ材の溶着不良が発生することがあるという不都合がある。 However, in the conventional reinforcing method, the rib material formed from a molten resin is pressed against the metal plate by the pressing roller to form the composite structure. Depending on the shape of the rib material, the rib material is molded. As the mechanism becomes complicated, the rib material needs to be cooled and solidified, resulting in a disadvantage that the formation speed of the composite is lowered. Further, the conventional reinforcing method has a disadvantage that the temperature of the heated metal plate is lowered during the transfer by the transfer robot, and the welding failure of the rib material may occur.
そこで、図3に示すように、熱可塑性樹脂製長尺状成形体からなる補強部材Pを連続供給しながら、肉薄の金属板Mの表面に1対の押圧ローラ21,21で押圧して溶着することが考えられる。このとき、補強部材Pは、電熱ヒータ管22及び第1のホットエア噴射機23で溶着可能に加熱されている。また、金属板Mは、第2のホットエア噴射機24で加熱されている。そして、前記溶着の後に、冷却エア噴射機25で金属板M及び補強部材Pを冷却することにより、金属板Mの片面に補強部材Pを設けた複合構造体を形成する。補強部材Pは、長尺状成形体であるので、必要に応じてカッタ26で所定の長さに切断される。
Therefore, as shown in FIG. 3, while continuously supplying the reinforcing member P made of a long thermoplastic resin molded body, the surface of the thin metal plate M is pressed and welded by a pair of pressing rollers 21 and 21. It is possible to do. At this time, the reinforcing member P is heated by the
しかし、図3の装置による補強方法によれば、金属板Mが肉薄であることから第2のホットエア噴射機24による加熱で変形し易く、得られる複合構造体の外観を損ねる虞がある。
However, according to the reinforcing method by the apparatus of FIG. 3, since the metal plate M is thin, it is likely to be deformed by heating with the second
そこで、本発明は、金属板等の被補強部材の変形を防止しつつ、該被補強部材に補強部材を溶着することができる補強方法及び装置を提供することを目的とする。 Then, an object of this invention is to provide the reinforcement method and apparatus which can weld a reinforcement member to this to-be-reinforced member, preventing a deformation | transformation of to-be-reinforced members, such as a metal plate.
前記目的を達成するために、本発明の補強方法は、熱可塑性樹脂からなる補強部材により被補強部材を補強する補強方法であって、該補強部材として該被補強部材に対する当接部にのみ磁性体を含有する熱可塑性樹脂製成形体を供給する工程と、誘導加熱により該当接部を溶着可能に加熱する工程と、該当接部が加熱された該補強部材を該被補強部材に溶着する工程とを備えることを特徴とする。 To achieve the above object, the reinforcing method of the present invention, the reinforcing member made of thermoplastic resin A reinforcing method which reinforces the target reinforcing member, only the contact portion against該被reinforcing member as the reinforcing member magnetic Supplying a molded body made of a thermoplastic resin containing a body, heating the applicable contact portion by induction heating so that the corresponding contact portion can be welded, and welding the reinforcing member heated to the corresponding contact portion to the member to be reinforced It is characterized by providing.
本発明の補強方法では、まず、供給された補強部材の当接部を誘導加熱によって溶着可能に加熱する。このとき、前記当接部は、含有された磁性体が前記誘導加熱によって加熱され、該磁性体から該当接部全体に熱伝導することにより、前記熱可塑性樹脂の軟化温度以上の目標温度範囲に加熱される。次に、前記当接部が溶着可能に加熱された前記補強部材を前記被補強部材に溶着することにより、該補強部材と前記被補強部材とが一体化されて該被補強部材を補強することができる。 In the reinforcing method of the present invention, first, the contact portion of the supplied reinforcing member is heated so as to be welded by induction heating. At this time, the contact portion is heated to the target temperature range equal to or higher than the softening temperature of the thermoplastic resin by heating the contained magnetic body by the induction heating and conducting heat from the magnetic body to the entire contact portion. Heated. Next, the reinforcing member and the member to be reinforced are integrated to reinforce the member to be reinforced by welding the reinforcing member heated so that the contact portion can be welded to the member to be reinforced. Can do.
本発明の補強方法によれば、前記誘導加熱によって前記補強部材の前記当接部は加熱されるものの前記被補強部材は全く加熱されないので、該被補強部材の変形を防止することができる。 According to the reinforcing method of the present invention, although the contact portion of the reinforcing member is heated by the induction heating, the member to be reinforced is not heated at all, so that deformation of the member to be reinforced can be prevented.
尚、本発明の補強方法において、前記補強部材は、所定の長さを備えるものであってもよく、長尺体であってもよい。 Incidentally, in the reinforcing method of the present invention, before Kiho strong member may be one having a predetermined length, it may be a long body.
ところで、本発明の補強方法においては、前記磁性体から前記当接部全体に熱伝導するとき、該当接部の一部分が過剰に昇温し前記熱可塑性樹脂の軟化温度を大きく上回って劣化温度に達すると、該当接部が熱劣化する虞がある。 By the way, in the reinforcing method of the present invention, when conducting heat from the magnetic body to the entire contact portion, a part of the contact portion is excessively heated to greatly deteriorate the softening temperature of the thermoplastic resin to the deterioration temperature. If it reaches, there is a possibility that the corresponding contact portion is thermally deteriorated.
そこで、本発明の補強方法において、前記当接部を溶着可能に加熱する工程は、該当接部を前記熱可塑性樹脂の軟化温度以上且つ劣化温度未満の温度範囲に加熱することが好ましい。
また、本発明の補強方法において、前記当接部を溶着可能に加熱する工程は、互いに昇温速度が異なる複数の加熱工程を備えることが好ましい。前記昇温速度が異なる複数の加熱工程を組み合わせることにより、前記補強部材を、前記熱可塑性樹脂の軟化温度以上且つ劣化温度未満の目標温度範囲に確実に制御して加熱することができる。
Therefore, in the reinforcing method of the present invention, the step of heating the contact portion so as to be welded preferably heats the contact portion to a temperature range not lower than the softening temperature of the thermoplastic resin and lower than the deterioration temperature.
In the reinforcing method of the present invention, it is preferable that the step of heating the contact portion so as to be welded includes a plurality of heating steps having different heating rates. By combining a plurality of heating steps with different heating rates, the reinforcing member can be reliably controlled and heated to a target temperature range that is not lower than the softening temperature and lower than the deterioration temperature of the thermoplastic resin.
また、前記複数の加熱工程を備える補強方法では、該複数の加熱工程は、前記補強部材の供給側ほど昇温速度が大きく排出側ほど昇温速度が小さくなるように行うことが好ましい。この場合には、まず、前記当接部を大きい昇温速度で加熱した後に、前記補強部材を前記供給側から排出側に移動させ、次に、該当接部を該供給側よりも小さい昇温速度で前記軟化温度以上の目標温度範囲に加熱する。前記補強部材の排出側において前記当接部を小さい昇温速度で加熱するので、該当接部を前記軟化温度以上の目標温度範囲により確実に制御して加熱することができる。 In the reinforcing method including the plurality of heating steps, the plurality of heating steps are preferably performed such that the temperature rising rate is higher on the supply side of the reinforcing member and the temperature rising rate is lower on the discharge side. In this case, first, the contact portion is heated at a high temperature rising rate, then the reinforcing member is moved from the supply side to the discharge side, and then the temperature of the contact portion is smaller than that of the supply side. Heat to a target temperature range above the softening temperature at a rate. Since the contact portion is heated at a small temperature increase rate on the discharge side of the reinforcing member, the contact portion can be reliably controlled and heated in a target temperature range equal to or higher than the softening temperature.
また、本発明の補強方法は、熱可塑性樹脂からなる補強部材により被補強部材を補強する補強装置であって、該被補強部材に対する当接部にのみ磁性体を含有する熱可塑性樹脂製成形体からなる該補強部材を供給する供給手段と、誘導加熱により該当接部を溶着可能に加熱する誘導加熱手段と、該当接部が加熱された該補強部材を該被補強部材に押圧する押圧手段とを備えることを特徴とする補強装置によって有利に実施することができる。 Further, the reinforcing method of the present invention is a reinforcing device that reinforces a member to be reinforced with a reinforcing member made of a thermoplastic resin, and is a molded body made of a thermoplastic resin that contains a magnetic substance only in a contact portion with the member to be reinforced. Supply means for supplying the reinforcing member, induction heating means for heating the corresponding contact part by induction heating so as to be welded, and pressing means for pressing the reinforcement member heated at the corresponding contact part against the member to be reinforced It can be carried out advantageously by means of a reinforcing device characterized in that
また、本発明の補強装置において、前記誘導加熱手段は、前記当接部を前記熱可塑性樹脂の軟化温度以上且つ劣化温度未満の温度範囲に加熱することが好ましい。
また、本発明の補強装置において、前記誘導加熱手段は、互いに磁束密度が異なる複数の誘導加熱手段を備えることが好ましい。前記磁束密度が異なることにより昇温速度が異なる複数の誘導加熱手段を組み合わせることにより、前記補強部材を、前記熱可塑性樹脂の軟化温度以上の目標温度範囲に確実に制御して加熱することができる。
In the reinforcing device according to the aspect of the invention, it is preferable that the induction heating unit heats the abutting portion to a temperature range higher than a softening temperature of the thermoplastic resin and lower than a deterioration temperature.
In the reinforcing device of the present invention, it is preferable that the induction heating means includes a plurality of induction heating means having different magnetic flux densities. By combining a plurality of induction heating means having different heating rates due to different magnetic flux densities, the reinforcing member can be reliably controlled and heated to a target temperature range equal to or higher than the softening temperature of the thermoplastic resin. .
また、前記複数の誘導加熱手段は、前記補強部材の供給側ほど磁束密度が大きく排出側ほど磁束密度が小さくなるように設けられていることが好ましい。この場合には、まず、前記補強部材の供給側に設けられた磁束密度の大きい誘導加熱手段により、前記当接部を加熱した後に、前記補強部材を前記供給側から排出側に移動させる。次に、前記補強部材の排出側に設けられ該供給側よりも磁束密度の小さい誘導加熱手段により、前記供給側の誘導加熱手段により加熱された前記当接部を前記軟化温度以上の目標温度範囲に加熱する。前記補強部材の排出側において前記当接部を磁束密度の小さい誘導加熱手段により小さい昇温速度で加熱するので、該当接部を前記軟化温度以上且つ劣化温度未満の目標温度範囲に確実に制御することができる。 The plurality of induction heating means are preferably provided such that the magnetic flux density increases toward the supply side of the reinforcing member and decreases toward the discharge side. In this case, first, the contact member is heated by induction heating means having a high magnetic flux density provided on the supply side of the reinforcement member, and then the reinforcement member is moved from the supply side to the discharge side. Next, the contact portion heated by the induction heating means on the supply side is provided at the discharge side of the reinforcing member and has a magnetic flux density smaller than that on the supply side. Heat to. Since the contact portion is heated to the induction heating means having a small magnetic flux density at a lower temperature increase rate on the discharge side of the reinforcing member, the contact portion is reliably controlled to a target temperature range that is higher than the softening temperature and lower than the deterioration temperature. be able to.
次に、添付の図面を参照しながら本発明の実施形態についてさらに詳しく説明する。 Next, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.
図1に示す本実施形態の補強装置1は、自動車用外装部品に用いられる例えば厚さ0.7mmの鉄鋼製の金属板Mを被補強部材として用い、その片面に熱可塑性樹脂からなる補強部材Pを溶着することにより補強する装置である。 A reinforcing device 1 according to this embodiment shown in FIG. 1 uses a steel metal plate M having a thickness of 0.7 mm, for example, used for an automobile exterior part as a member to be reinforced, and a reinforcing member made of a thermoplastic resin on one side thereof. It is a device that reinforces by welding P.
補強部材Pは、図2に示すように補強部Paと当接部Pbとの二層構造の長尺状成形体からなり、該当接部Pbが金属板Mに当接して溶着される。補強部Paは、例えばグラスファイバーを20質量%含有するナイロン6等の熱可塑性樹脂からなる。一方、当接部Pbは、例えばスチレン系エラストマー等の熱可塑性樹脂からなり、磁性体Fが分散されている。磁性体Fは、例えばフェライト系SUS、鉄鋼、軟鉄、鋼鉄、ニッケル等からなり、直径80〜150μm、長さ1〜3mmの繊維状であり、当接部Pb全体に対して30〜60質量%含有されている。 As shown in FIG. 2, the reinforcing member P is formed of a long-shaped molded body having a two-layer structure including a reinforcing portion Pa and a contact portion Pb, and the corresponding contact portion Pb contacts and is welded to the metal plate M. The reinforcing portion Pa is made of a thermoplastic resin such as nylon 6 containing 20% by mass of glass fiber, for example. On the other hand, the contact portion Pb is made of, for example, a thermoplastic resin such as a styrene elastomer, and the magnetic material F is dispersed therein. The magnetic body F is made of, for example, ferritic SUS, steel, soft iron, steel, nickel, etc., and has a fibrous shape with a diameter of 80 to 150 μm and a length of 1 to 3 mm, and is 30 to 60% by mass with respect to the entire contact part Pb. Contained.
補強部材Pは、例えば、次のようにして得ることができる。まず、ペレット状のスチレン系エラストマーと繊維状の磁性体Fとを混合した混合物を溶融して棒状に押出成形する。次に、得られた押出成形体を裁断して得られた第1のペレットと、グラスファイバーを含むナイロン6からなる第2のペレットとをそれぞれ溶融する。次に、上下に重ねて設けられた2つのダイの一方から第1のペレットを溶融した第1の溶融樹脂を板状に押出成形するとともに、第1の溶融樹脂の押出成形体の上に、他方のダイから第2のペレットを溶融した第2の溶融樹脂を板状に押出成形する。この結果、スチレン系エラストマー及び磁性体Fの混合物からなる板状の押出成形体の上に、グラスファイバーを含むナイロン6からなる板状の押出成形体が積層され、その後冷却して固化することにより、補強部Paと当接部Pbとの二層構造の長尺状成形体からなる補強部材Pを得ることができる。 The reinforcing member P can be obtained, for example, as follows. First, a mixture obtained by mixing a pellet-like styrenic elastomer and a fibrous magnetic material F is melted and extruded into a rod shape. Next, the first pellet obtained by cutting the obtained extrusion-molded body and the second pellet made of nylon 6 containing glass fiber are melted. Next, while extruding the first molten resin obtained by melting the first pellet from one of the two dies that are provided one above the other in a plate shape, on the extruded body of the first molten resin, A second molten resin obtained by melting the second pellet from the other die is extruded into a plate shape. As a result, a plate-like extrudate made of nylon 6 containing glass fibers is laminated on a plate-like extrudate made of a mixture of styrene elastomer and magnetic substance F, and then cooled and solidified. In addition, the reinforcing member P made of a long molded body having a two-layer structure of the reinforcing portion Pa and the contact portion Pb can be obtained.
補強装置1は、ボビンBに巻回された長尺状成形体の補強部材Pを中継ローラRを介して引き出し、補強部材Pを、その始端側から末端側に向かって順に、ジグJに載置された金属板Mの片面に溶着することにより金属板Mを補強する。補強装置1は、筐体2内に収容されていて、図示しないロボットにより金属板Mの上方において任意の位置に移動可能である。筐体2には、補強部材Pを内部に供給する供給口2aと、補強部材Pが排出される排出口2bとが設けられている。
The reinforcing device 1 pulls out the reinforcing member P of the elongated molded body wound around the bobbin B through the relay roller R, and places the reinforcing member P on the jig J in order from the start end side to the end side. The metal plate M is reinforced by welding to one side of the placed metal plate M. The reinforcing device 1 is accommodated in the
補強装置1は、供給口2aに近い側から遠い側へ順に、ボビンBに巻回された補強部材Pを引き出して筐体2内に連続供給する1対の送りローラ3と、補強部材Pの当接部Pbを誘導加熱によって溶着可能に加熱する誘導加熱機4と、補強部材Pを所定の位置で切断するカッタ5と、筐体2の底部に設けられ、排出口2bから排出された補強部材Pを金属板Mに押圧する1対の押圧ローラ6とを備える。また、補強装置1は、誘導加熱機4の下方の筐体2の底部に設けられ、金属板Mの表面を脱脂洗浄する大気プラズマ洗浄機7を備える。
The reinforcing device 1 includes a pair of
誘導加熱機4は、補強部材Pの供給側に設けられた第1の誘導加熱コイル4aと、該補強部材Pの排出側に設けられた第2の誘導加熱コイル4bとを備える。第1の誘導加熱コイル4aは、第2の誘導加熱コイル4bよりも大きい磁束密度を有しており、第2の誘導加熱コイル4bよりも大きい昇温速度で補強部材Pの当接部Pbを加熱することができる。第1の誘導加熱コイル4aは、例えば、コイル単位長さにおける巻数を大きくしたり、コイル長さを短くすることにより、第2のコイル4bよりも大きい磁束密度に設定することができる。 The induction heater 4 includes a first induction heating coil 4a provided on the supply side of the reinforcing member P, and a second induction heating coil 4b provided on the discharge side of the reinforcing member P. The first induction heating coil 4a has a magnetic flux density larger than that of the second induction heating coil 4b, and the contact portion Pb of the reinforcing member P is moved at a temperature rising rate higher than that of the second induction heating coil 4b. Can be heated. The first induction heating coil 4a can be set to a magnetic flux density larger than that of the second coil 4b, for example, by increasing the number of turns in the coil unit length or shortening the coil length.
本実施形態では、誘導加熱機4は2つの誘導加熱コイル4a,4bとを備えるとしているが、複数の誘導加熱コイルが補強部材Pの供給側ほど磁束密度が大きく排出側ほど磁束密度が小さくなるように設けられていればよく、その数は限定されない。 In the present embodiment, the induction heater 4 includes two induction heating coils 4a and 4b. However, the plurality of induction heating coils have a higher magnetic flux density on the supply side of the reinforcing member P and a lower magnetic flux density on the discharge side. The number is not limited as long as it is provided.
次に、補強装置1による金属板Mの補強方法を説明する。まず、ボビンBに巻回された長尺状成形体の補強部材Pを中継ローラRを介して送りローラ3で引き出し、誘導加熱機4の第1の誘導加熱コイル4a及び第2の誘導加熱コイル4bの内方へ連続供給する。このとき、補強部材Pは、当接部Pbが金属板Mに対向するように供給される。
Next, a method for reinforcing the metal plate M by the reinforcing device 1 will be described. First, the reinforcing member P of the long molded body wound around the bobbin B is pulled out by the
次に、誘導加熱機4によって補強部材Pの当接部Pbを誘導加熱することにより、当接部Pbを溶着可能に加熱する。当接部Pbは、含有された磁性体Fが前記誘導加熱によって加熱され、磁性体Fから当接部Pb全体に熱伝導することにより、前記熱可塑性樹脂の軟化温度以上且つ劣化温度未満の目標温度範囲に加熱される。 Next, the contact portion Pb of the reinforcing member P is induction-heated by the induction heater 4 to heat the contact portion Pb so as to be welded. The abutting portion Pb is heated by the induction heating to contain the magnetic material F, and conducts heat from the magnetic material F to the entire abutting portion Pb, thereby achieving a target that is equal to or higher than the softening temperature of the thermoplastic resin and lower than the deterioration temperature. Heated to a temperature range.
具体的には、まず、第1の誘導加熱コイル4aにより、当接部Pbを例えば350℃/秒の大きい昇温速度で前記熱可塑性樹脂の軟化温度未満で該軟化温度に近い温度まで加熱する。 Specifically, first, the first induction heating coil 4a heats the contact portion Pb to a temperature close to the softening temperature below the softening temperature of the thermoplastic resin at a high temperature rising rate of 350 ° C./second, for example. .
次に、補強部材Pが供給側から排出側へ移動した後に、第2の誘導加熱コイル4bにより、当接部Pbを例えば200℃/秒の小さい昇温速度で加熱する。このとき、第2の誘導加熱コイル4bは小さい昇温速度で昇温するので、前記熱可塑性樹脂の劣化温度に達することなく当接部Pbを前記目標温度範囲に確実に制御して加熱することができる。 Next, after the reinforcing member P moves from the supply side to the discharge side, the contact portion Pb is heated by the second induction heating coil 4b at a low temperature increase rate of, for example, 200 ° C./second. At this time, since the second induction heating coil 4b is heated at a small temperature rising rate, the contact portion Pb is reliably controlled to be heated to the target temperature range without reaching the deterioration temperature of the thermoplastic resin. Can do.
次に、当接部Pbが溶着可能に加熱された補強部材Pを、大気プラズマ洗浄機7によって脱脂洗浄された金属板Mと押圧ローラ6,6との間に供給する。このとき、金属板Mと押圧ローラ6との間に送り込まれる角度を小さくすることにより、補強部材P、特に加熱された前記当接部Pbにおいて前記角度の曲げによって生じる応力を低減することができる。 Next, the reinforcing member P heated so that the contact portion Pb can be welded is supplied between the metal plate M degreased and cleaned by the atmospheric plasma cleaner 7 and the pressing rollers 6 and 6. At this time, by reducing the angle fed between the metal plate M and the pressing roller 6, it is possible to reduce the stress caused by the bending of the angle in the reinforcing member P, particularly the heated contact portion Pb. .
次に、当接部Pbが加熱された補強部材Pを押圧ローラ6で金属板Mの表面に押圧する。このとき、前記誘導加熱によって当接部Pbが溶着可能に加熱されているので、金属板Mを加熱しなくても当接部Pbを金属板Mの片面に溶着することができ、補強部材Pと金属板Mとを一体化して金属板Mを補強することができる。 Next, the reinforcing member P heated by the contact portion Pb is pressed against the surface of the metal plate M by the pressing roller 6. At this time, since the contact part Pb is heated by the induction heating so as to be welded, the contact part Pb can be welded to one side of the metal plate M without heating the metal plate M, and the reinforcing member P And the metal plate M can be integrated to reinforce the metal plate M.
そして、金属板Mに溶着された補強部材Pの長さが金属板Mの補強すべき所定の長さに近づいたとき、カッタ5で補強部材Pを切断することにより補強部材Pの供給が停止する。また、切断された補強部材Pを押圧ローラ6,6で押圧して補強部材Pの末端まで金属板Mに溶着することにより、金属板Mが所定の長さの補強部材Pにより補強される。
Then, when the length of the reinforcing member P welded to the metal plate M approaches a predetermined length to be reinforced of the metal plate M, the supply of the reinforcing member P is stopped by cutting the reinforcing member P with the
補強装置1は、図示しないロボットを介して長尺状成形体の補強部材Pの始端側から末端側に向かって移動するとともに金属板Mの幅方向に移動しながら、上記の動作を繰り返し行う。 The reinforcing device 1 repeats the above operation while moving from the starting end side to the terminal end side of the reinforcing member P of the elongated shaped body via a robot (not shown) and moving in the width direction of the metal plate M.
本実施形態の補強装置1によれば、前記誘導加熱によって補強部材Pの当接部Pbは加熱されるものの金属板Mは全く加熱されないので、金属板Mの変形を防止することができる。 According to the reinforcing device 1 of the present embodiment, the contact portion Pb of the reinforcing member P is heated by the induction heating, but the metal plate M is not heated at all. Therefore, deformation of the metal plate M can be prevented.
また、本実施形態の補強装置1によれば、補強部材Pの当接部Pbが金属板Mに溶着可能な程度に加熱されていればよく、補強部Pa及び金属板Mを加熱する必要がないので、金属板Mの補強に要するエネルギーを低減することができる。また、補強装置1全体において加熱されるのは当接部Pbだけであり、当接部Pb自体は小さいために短時間で冷却されるので、冷却設備を設ける必要がなく、装置構成を簡単なものにすることができる。 Further, according to the reinforcing device 1 of the present embodiment, it is sufficient that the contact portion Pb of the reinforcing member P is heated to such an extent that it can be welded to the metal plate M, and it is necessary to heat the reinforcing portion Pa and the metal plate M. Therefore, the energy required for reinforcing the metal plate M can be reduced. Further, only the abutting portion Pb is heated in the entire reinforcing device 1, and since the abutting portion Pb itself is small, it is cooled in a short time, so there is no need to provide a cooling facility, and the device configuration is simple. Can be a thing.
さらに、本実施形態の補強装置1によれば、昇温速度が異なる複数の誘導加熱コイル4a,4bを備えるので、当接部Pbを過剰に加熱して熱劣化させることを防止し、該当接部Pbを前記軟化温度以上且つ劣化温度未満の目標温度範囲に確実に制御することができる。 Furthermore, according to the reinforcing device 1 of the present embodiment, since the plurality of induction heating coils 4a and 4b having different heating rates are provided, it is possible to prevent the contact portion Pb from being excessively heated and thermally deteriorated. The part Pb can be reliably controlled within the target temperature range that is equal to or higher than the softening temperature and lower than the deterioration temperature.
また、本実施形態では、長尺状成形体からなる補強部材Pを溶着可能に加熱した後に、金属板Mに溶着する工程で該補強部材Pを所定の長さに切断しているが、予め所定の長さに切断された成形体からなる補強部材Pを溶着可能に加熱し金属板Mに溶着するようにしてもよい。 In this embodiment, the reinforcing member P made of a long shaped body is heated so as to be welded, and then the reinforcing member P is cut into a predetermined length in the step of welding to the metal plate M. The reinforcing member P made of a molded body cut to a predetermined length may be heated so as to be welded and welded to the metal plate M.
また、本実施形態では、補強部材が溶着される被補強部材として金属板Mを用いるとしているが、金属板Mに代えて樹脂製の板材を用いることも可能である。 In the present embodiment, the metal plate M is used as the member to be reinforced to which the reinforcing member is welded. However, a resin plate can be used instead of the metal plate M.
1…補強装置、 3…供給手段(送りローラ)、 4a,4b…誘導加熱手段(誘導加熱コイル)、 6…押圧手段、 F…磁性体、 M…金属板(被補強部材)、 P…補強部材、 Pb…当接部。 DESCRIPTION OF SYMBOLS 1 ... Reinforcing device, 3 ... Supply means (feed roller), 4a, 4b ... Induction heating means (induction heating coil), 6 ... Pressing means, F ... Magnetic body, M ... Metal plate (member to be reinforced), P ... Reinforcement Member, Pb ... contact part.
Claims (8)
該補強部材として該被補強部材に対する当接部にのみ磁性体を含有する熱可塑性樹脂製成形体を供給する工程と、
誘導加熱により該当接部を溶着可能に加熱する工程と、
該当接部が加熱された該補強部材を該被補強部材に溶着する工程とを備えることを特徴とする補強方法。 A reinforcing method for reinforcing a member to be reinforced with a reinforcing member made of a thermoplastic resin,
Supplying a thermoplastic resin molded body containing a magnetic material only to a contact portion with respect to the member to be reinforced as the reinforcing member;
A process of heating the corresponding contact part by induction heating so as to be welded;
And a step of welding the reinforcing member having the contact portion heated to the member to be reinforced.
前記当接部を溶着可能に加熱する工程は、該当接部を前記熱可塑性樹脂の軟化温度以上且つ劣化温度未満の温度範囲に加熱することを特徴とする補強方法。 The step of heating the contact portion so as to be welded includes heating the contact portion to a temperature range higher than the softening temperature of the thermoplastic resin and lower than the deterioration temperature.
前記当接部を溶着可能に加熱する工程は、互いに昇温速度が異なる複数の加熱工程を備えることを特徴とする補強方法。 In the reinforcing method according to claim 1 or 2 ,
The step of heating the contact portion so as to be welded includes a plurality of heating steps having different heating rates.
前記複数の加熱工程は、前記補強部材の供給側ほど昇温速度が大きく排出側ほど昇温速度が小さくなるように行うことを特徴とする補強方法。 The reinforcing method according to claim 3 ,
The reinforcing method is characterized in that the plurality of heating steps are performed such that the temperature rise rate is larger on the supply side of the reinforcing member and the temperature rise rate is smaller on the discharge side.
該被補強部材に対する当接部にのみ磁性体を含有する熱可塑性樹脂製成形体からなる該補強部材を供給する供給手段と、
誘導加熱により該当接部を溶着可能に加熱する誘導加熱手段と、
該当接部が加熱された該補強部材を該被補強部材に押圧する押圧手段とを備えることを特徴とする補強装置。 A reinforcing device for reinforcing a member to be reinforced with a reinforcing member made of a thermoplastic resin,
Supply means for supplying the reinforcing member made of a thermoplastic resin molded body containing a magnetic material only in the contact portion with the member to be reinforced;
Induction heating means for heating the corresponding contact part by induction heating so as to be welded;
A reinforcing device, comprising: a pressing unit that presses the reinforcing member whose contact portion is heated against the member to be reinforced.
前記誘導加熱手段は、前記当接部を前記熱可塑性樹脂の軟化温度以上且つ劣化温度未満の温度範囲に加熱することを特徴とする補強装置。 The said induction heating means heats the said contact part to the temperature range more than the softening temperature of the said thermoplastic resin, and less than deterioration temperature, The reinforcement apparatus characterized by the above-mentioned.
前記誘導加熱手段は、互いに磁束密度が異なる複数の誘導加熱手段を備えることを特徴とする補強装置。 The reinforcing device according to claim 5 or 6 ,
The induction heating means includes a plurality of induction heating means having different magnetic flux densities from each other.
前記複数の誘導加熱手段は、前記補強部材の供給側ほど磁束密度が大きく排出側ほど磁束密度が小さくなるように設けられていることを特徴とする補強装置。 The reinforcing device according to claim 7 , wherein
The plurality of induction heating means are provided such that the magnetic flux density is larger on the supply side of the reinforcing member and the magnetic flux density is smaller on the discharge side.
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