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JP5514434B2 - Self-propelled aerial work vehicle and battery mounting position determination method for self-propelled aerial work vehicle - Google Patents

Self-propelled aerial work vehicle and battery mounting position determination method for self-propelled aerial work vehicle Download PDF

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JP5514434B2
JP5514434B2 JP2008328305A JP2008328305A JP5514434B2 JP 5514434 B2 JP5514434 B2 JP 5514434B2 JP 2008328305 A JP2008328305 A JP 2008328305A JP 2008328305 A JP2008328305 A JP 2008328305A JP 5514434 B2 JP5514434 B2 JP 5514434B2
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chassis
deck
aerial work
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work vehicle
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JP2010149964A (en
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勝美 谷川
政樹 有村
則英 五十嵐
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HOKUETSU INDUSTRIES CO., LTD.
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Description

本発明は,高所作業に用いられる自走式高所作業車,及び自走式高所作業車におけるバッテリの搭載位置決定方法に関し,より詳しくは,車台上にシザースリンク機構からなる昇降手段を介して昇降するデッキを備えた高所作業車において,該自走式高所作業車に搭載された電源用バッテリの配置に特徴を有する自走式高所作業車,及び前記バッテリの搭載位置の決定方法に関する。   The present invention relates to a self-propelled aerial work vehicle used for aerial work and a method for determining a battery mounting position in a self-propelled aerial work vehicle, and more specifically, a lifting means comprising a scissor link mechanism on a chassis. A self-propelled aerial work vehicle characterized by the arrangement of a power battery mounted on the self-propelled aerial work vehicle, and a mounting position of the battery. Regarding the determination method.

従来,例えば建築現場における天井施工,天井(天井裏を含む)及び壁面高所における照明取付工事あるいは塗装工事等のような高所作業は足場を組立てて行っていたが,最近では作業の省力化と安全性を図るために自走式高所作業車が多用されている。   Conventionally, for example, ceiling work at construction sites, lighting installation work or painting work at ceilings (including the back of the ceiling) and wall heights have been assembled as scaffolds, but recently labor saving Self-propelled aerial work platforms are often used for safety.

この自走式高所作業車は,一例として図5,図6に示すように車輪やクローラ等の走行手段133(図示の例では車輪)を備えた車台130上に,作業者等を乗せて昇降するデッキ110を備えると共に,このデッキ110を車台130上で昇降させるための昇降機構120を備えたもので,モータによって駆動される車輪等の走行手段を備えた自走式高所作業車は機動性が高く,操作し易いことから,屋内の電気工事や内装工事などで広く使用されている。   As an example, this self-propelled aerial work vehicle has an operator or the like placed on a chassis 130 equipped with traveling means 133 (wheels in the illustrated example) such as wheels and crawlers as shown in FIGS. A self-propelled aerial work vehicle including a deck 110 that moves up and down and a lifting mechanism 120 that lifts and lowers the deck 110 on a chassis 130. The vehicle is equipped with traveling means such as wheels driven by a motor. Because it is highly mobile and easy to operate, it is widely used for indoor electrical work and interior work.

このような自走式高所作業車100にあっては,電源としてのバッテリ134を車台130に搭載し,このバッテリ134からの電力供給により自走のための車輪の駆動,デッキ110の昇降のいずれ共に行うものであるために,比較的大型のバッテリ134が搭載されており,そのため,このようなバッテリ134の搭載スペースを確保すると共に,メンテナンス性の向上を可能としたバッテリの配置についての各種の提案もなされている。   In such a self-propelled aerial work vehicle 100, a battery 134 as a power source is mounted on the chassis 130, and power is supplied from the battery 134 to drive wheels for self-propulsion and to raise and lower the deck 110. Since both of them are carried out, a relatively large battery 134 is mounted. For this reason, various types of battery arrangements that secure the mounting space for such a battery 134 and improve the maintainability are provided. Has also been proposed.

このような自走式高所作業車の一例として,車台上に,伸縮マストを介してデッキを昇降可能に取り付けた自走式高所作業車において,車台に設けられたバッテリのメンテナンス性を向上するために,車台の幅方向両側面を貫通するように開口するバッテリ収容部内に,車台の幅方向にバッテリを収容するように構成すると共に,車台の両側面のいずれ側からもバッテリを挿入および引出をすることができるように構成した自走式高所作業車が提案されている(特許文献1参照)。   As an example of such a self-propelled aerial work vehicle, in a self-propelled aerial work vehicle in which the deck is mounted on the chassis via a telescopic mast so that the deck can be raised and lowered, the maintainability of the battery provided on the chassis is improved. In order to achieve this, the battery is accommodated in the battery housing in the width direction of the chassis, and the battery is inserted and inserted from either side of the chassis. A self-propelled aerial work vehicle configured to be able to be pulled out has been proposed (see Patent Document 1).

また,バッテリに,自走式高所作業車を安定させるための錘としての機能を持たせることも提案されており,このような高所作業車の一例として,シザースリンク機構によってデッキを昇降可能とした自走式高所作業車において,車台の幅を,デッキの幅に対して大きく形成し,この車台の走行方向前後方向の略中間位置において車台の左右両側に一対のバッテリをそれぞれ収容することにより,作業台の上昇時,自走式高所作業車の幅方向における安定性を向上させることも提案されている(特許文献2参照)。   In addition, it has been proposed that the battery has a function as a weight for stabilizing the self-propelled aerial work vehicle. As an example of such a high work vehicle, the deck can be raised and lowered by a scissor link mechanism. In the self-propelled aerial work vehicle, the width of the chassis is made larger than the width of the deck, and a pair of batteries are accommodated on the left and right sides of the chassis at approximately the middle position in the longitudinal direction of the chassis. Thus, it has also been proposed to improve the stability of the self-propelled aerial work vehicle in the width direction when the work table is raised (see Patent Document 2).

この発明の先行技術文献情報としては下記のものがある。
特開2004−299851号公報 特開2006−206260号公報
Prior art document information of the present invention includes the following.
JP 2004-299851 A JP 2006-206260 A

以上で紹介した特許文献1,2に記載の自走式高所作業車では,いずれもバッテリを車台の走行方向前後方向における略中心位置に搭載するものとなっている(特許文献1の図1,特許文献2の図1参照)。   In the self-propelled aerial work vehicle described in Patent Documents 1 and 2 introduced above, the battery is mounted at a substantially central position in the front-rear direction of the traveling direction of the chassis (FIG. 1 of Patent Document 1). , See FIG. 1 of Patent Document 2).

ここで,上記従来技術のうち,例えば特許文献1に記載された自走式高所作業車のように,伸縮マストによってデッキを昇降させる構成では,デッキの下降時および上昇時のいずれの場合においても,自走式高所作業車の平面視における重心は変化しない。   Here, among the above prior arts, for example, in the configuration in which the deck is raised and lowered by the telescopic mast as in the self-propelled aerial work vehicle described in Patent Document 1, the deck is lowered or raised. However, the center of gravity of a self-propelled aerial work vehicle in plan view does not change.

しかし,例えば特許文献2として紹介したように,デッキをシザースリンク機構によって昇降する構成の自走式高所作業車にあっては,図5,6に示した自走式高所作業車100と同様,シザースリンク機構120の最下段を構成するX字状リンク121aの一方のアーム121’の下端を,車台130の一端130a側の所定の位置に枢着されていると共に,他方のアーム121’’の下端は,車台130の長さ方向に移動可能に車台上に取り付けているため,図5(B)に示すデッキ110の最下降位置から,図6(B)に示すデッキ110の最上昇位置にシザースリンク機構120を伸長させると,シザースリンク機構120は,車台130の一端130a側に偏って配置されることとなるために,自走式高所作業車100全体の重心も車台30の一端30a側に移動する。   However, as introduced in Patent Document 2, for example, in the self-propelled aerial work vehicle configured to move the deck up and down by the scissor link mechanism, the self-propelled aerial work vehicle 100 shown in FIGS. Similarly, the lower end of one arm 121 ′ of the X-shaped link 121a constituting the lowest stage of the scissor link mechanism 120 is pivotally attached to a predetermined position on the one end 130a side of the chassis 130, and the other arm 121 ′. Since the lower end of 'is mounted on the chassis so as to be movable in the longitudinal direction of the chassis 130, the lowest rise of the deck 110 shown in FIG. 6 (B) from the lowest position of the deck 110 shown in FIG. 5 (B). When the scissor link mechanism 120 is extended to the position, the scissor link mechanism 120 is biased toward the one end 130a side of the chassis 130, so that the center of gravity of the entire self-propelled aerial work vehicle 100 is obtained. Moves to one end 30a side of the chassis 30.

しかも,図6(B)に示すように,デッキ110の一端110a側にこの自走式高所作業車100の走行,操舵,デッキ110の昇降等を操作するための操作盤113が設けられている場合には,作業者はデッキ110上の一端110a寄りに搭乗してこの操作盤113を操作することとなるために,デッキ110の一端110a側にはさらにこの作業者の体重が荷重としてかかり,図6(B)中に矢印で示す方向に転倒し易いものとなる。   In addition, as shown in FIG. 6B, an operation panel 113 for operating the self-propelled aerial work platform 100, steering, raising and lowering the deck 110, etc. is provided on the one end 110a side of the deck 110. In this case, the operator gets on the deck 110 near the one end 110a and operates the operation panel 113. Therefore, the weight of the worker is further applied as a load to the one end 110a side of the deck 110. 6B easily falls in the direction indicated by the arrow in FIG.

更に,例えば図7に示すように,作業を行うべき壁面等の地表部に基礎が張り出す等して自走式高所作業車100を壁面に対して近付けることができない場合,デッキ110が壁面から離間した状態となるために作業を行い難く,例えばデッキ110を壁面側にスライドさせて迫り出させる等して壁面に対して近付けることができれば便利であるが,このような構成を採用し,作業者がデッキ110のスライドによって迫り出した部分に搭乗すれば,作業者の体重移動によって自走式高所作業車100は,更に図6(B)中に矢印で示す方向に転倒し易くなる。   Furthermore, as shown in FIG. 7, for example, when the foundation cannot be brought close to the wall surface due to the foundation overhanging the ground surface such as the wall surface on which the work should be performed, the deck 110 is placed on the wall surface. For example, it is convenient if the deck 110 can be brought close to the wall surface by sliding the deck 110 to the wall surface side, for example. If the worker gets on the portion that is pushed out by the slide of the deck 110, the self-propelled aerial work vehicle 100 is more likely to fall in the direction indicated by the arrow in FIG. .

そのため,昇降機構としてザースリンク機構を備えた自走式高所作業車,特に作業者の体重移動による影響を受け易い比較的小型の自走式高所作業車において,デッキにこのようなスライド機構を採用することが困難なものとなっていた。   For this reason, in a self-propelled aerial work platform equipped with a sers link mechanism as an elevating mechanism, particularly a relatively small self-propelled aerial work vehicle that is easily affected by weight shift of an operator, such a slide mechanism is provided on the deck. It was difficult to adopt.

このようなシザースリンク機構の伸長によって生じる重心の移動,デッキのスライドによる迫り出し等によって生じる重心の移動や作業者の搭乗位置の変化に伴う荷重の移動を補償するためには,例えば車台130の他端130b側に予めカウンタウエイト150等を取り付けておくことも考えられるが,このようなカウンタウエイト150の取り付けにより自走式高所作業車100の重量は大幅に増大することとなり,特に小型軽量であるために使い勝手の良い,比較的小型の自走式高所作業車に対してこのようなカウンタウエイトを取り付ければ,その長所が失われることとなる。   In order to compensate for the movement of the center of gravity caused by the extension of the scissor link mechanism, the movement of the center of gravity caused by the sliding of the deck, and the movement of the load accompanying the change in the boarding position of the operator, for example, Although it is conceivable that the counterweight 150 or the like is attached in advance to the other end 130b side, the weight of the self-propelled aerial work vehicle 100 is greatly increased by such attachment of the counterweight 150, and is particularly small and light. Therefore, if such a counterweight is attached to a relatively small self-propelled aerial work vehicle that is easy to use, the advantages will be lost.

なお,図5及び図6に示す自走式高所作業車100の構成では,走行手段として車台130の走行方向前後方向における両端130a,130b側にそれぞれ一対ずつ,計4輪の車輪133を設けた構成であり,この4輪のうちのいずれか1輪(場合によりこれと対を成す車輪との計2輪)を駆動輪としてモータによって駆動するものであるが,この種の自走式高所作業車100の車輪133には,スプリング等のサスペンション機構は一般に採用されておらず,車輪133は路面や床面等の走行面の起伏や凹凸に対する追従性が悪いものとなっている。   In the configuration of the self-propelled aerial work vehicle 100 shown in FIGS. 5 and 6, a total of four wheels 133 are provided as a traveling means, one pair on each of the both ends 130 a and 130 b in the longitudinal direction of the chassis 130. This type of vehicle is driven by a motor using any one of these four wheels (a total of two wheels, in some cases with a pair of wheels) as a driving wheel. A suspension mechanism such as a spring is generally not used for the wheel 133 of the work vehicle 100, and the wheel 133 is poor in conformity to undulations and unevenness of a running surface such as a road surface and a floor surface.

そのため,走行面に起伏や凹凸等が存在する場合において,4輪のうちの3輪が接地した状態にあると,残りの1輪は路面より浮いてしまうことになり,この浮いた状態の車輪が駆動輪である場合,自走式高所作業車100は,走行面に対して駆動力を伝達することができなくなる。   Therefore, when there are undulations or irregularities on the running surface, if three of the four wheels are in contact with the ground, the remaining one wheel will float off the road surface. Is a driving wheel, the self-propelled aerial work vehicle 100 cannot transmit the driving force to the traveling surface.

その一方で,前述のようなサスペンション機構を採用することは装置構成を複雑とし,部品点数の増加による組立工程数の増加等を招くことから,より簡単な構造で駆動輪の駆動力を確実に走行面に対して伝達し得る構成を得ることが望まれる。   On the other hand, the use of the suspension mechanism as described above complicates the device configuration and increases the number of assembly processes due to an increase in the number of parts, thereby ensuring the driving force of the drive wheels with a simpler structure. It is desired to obtain a configuration that can be transmitted to the running surface.

そこで本発明は,上記従来技術の欠点を解消するためになされたものであり,カウンタウエイト等を設けることなく,またはカウンタウエイトの重量を減らした場合であってもバランスが良く転倒等が生じ難いという安全性に優れたものであると共に,デッキの一端側を前方へ迫り出し可能とし,更に,走行時における駆動輪の駆動力を確実に走行面に対して伝えることができる自走式高所作業車を提供することを目的とする。   Therefore, the present invention has been made to solve the above-mentioned drawbacks of the prior art, and it is well balanced even when a counterweight or the like is not provided or the weight of the counterweight is reduced. This is a self-propelled high place where the one end side of the deck can be pushed forward, and the driving force of the driving wheels during traveling can be reliably transmitted to the traveling surface. The purpose is to provide a work vehicle.

上記目的を達成するための本発明の自走式高所作業車1及び自走式高所作業車におけるバッテリの搭載位置決定方法は,車輪やクローラ等の走行手段33を備えた車台30と,前記車台30上で昇降するデッキ10と,前記車台30と前記デッキ10間に配置されて前記デッキ10を昇降させる複数段のX字状リンク21a〜21d,22a〜22dによって構成されたシザースリンク機構20を備え,前記シザースリンク機構20の最下段におけるX字状リンク21a,22aを構成する一方のアーム211,221の下端を前記車台30の走行方向前後方向におけるいずれか一端30a寄りに枢着すると共に,他方のアーム212,222の下端を,車台30上に摺動可能に取り付け,更に,前記シザースリンク機構20の最上段におけるX字状リンク21d,22dを構成する一方のアーム211,221の上端を前記デッキ10の底部に摺動可能に取り付けると共に,他方のアーム212,222の上端を,前記車台30の一端30aと同一方向の一端10a寄りで前記デッキ10の底部に枢着した自走式高所作業車1において,
前記デッキ10が最下降した状態における前記自走式高所作業車1の平面視で,平面矩形状の前記車台30の各角部a〜dの対角線DLの交点xと,前記車台30の他端30bにおける角部c,dの三点により形成される三角形(三角形x,c,d)内に前記自走式高所作業車1の重心G L ,G LS 入るように,バッテリ34を前記車台30の他端30b側における前記車台30内に配置することを特徴とする(請求項1,請求項9)。
In order to achieve the above object, the self-propelled aerial work vehicle 1 and the battery mounting position determination method in the self-propelled aerial work vehicle of the present invention include a chassis 30 having travel means 33 such as wheels and crawlers, Scissor link mechanism composed of a deck 10 that moves up and down on the chassis 30 and a plurality of stages of X-shaped links 21a to 21d and 22a to 22d that are arranged between the chassis 30 and the deck 10 to raise and lower the deck 10. 20, the lower ends of the arms 211, 221 constituting the X-shaped links 21a, 22a in the lowermost stage of the scissor link mechanism 20 are pivotally attached to either one end 30a in the front-rear direction of the running direction of the chassis 30. At the same time, the lower ends of the other arms 212 and 222 are slidably mounted on the chassis 30, and are further installed at the uppermost stage of the scissor link mechanism 20. The upper ends of the arms 211 and 221 constituting the X-shaped links 21d and 22d are slidably attached to the bottom of the deck 10, and the upper ends of the other arms 212 and 222 are the same as the one end 30a of the chassis 30. In the self-propelled aerial work vehicle 1 pivotally attached to the bottom of the deck 10 near one end 10a in the direction,
In a plan view of the self-propelled aerial work platform 1 in the state where the deck 10 is lowered, the intersection x of the diagonal lines DL of the corners a to d of the chassis 30 having a rectangular plane and the other of the chassis 30 The battery 34 is placed so that the center of gravity G L , G LS of the self-propelled aerial work vehicle 1 falls within a triangle (triangle x, c, d) formed by three points c, d at the end 30b. It arrange | positions in the said chassis 30 in the other end 30b side of the said chassis 30 (Claim 1, Claim 9).

上記構成の自走式高所作業車1において,前記走行手段33を,前記車台30の走行方向前後方向における両端30a,30b側のそれぞれに一対ずつ設けられた車輪33a,33b;33c,33dとし,前記車台30の他端30b側に設けた一対の車輪33c,33dの少なくとも一方(図示の例では車輪33d)を駆動輪とすることが好ましい(請求項2)。   In the self-propelled aerial work vehicle 1 having the above-described configuration, the traveling means 33 is a pair of wheels 33a, 33b; 33c, 33d provided on both ends 30a, 30b in the longitudinal direction of the chassis 30. It is preferable that at least one of the pair of wheels 33c and 33d (the wheel 33d in the illustrated example) provided on the other end 30b side of the chassis 30 be a driving wheel.

さらに,上記構成の自走式高所作業車1及び当該作業車におけるバッテリの搭載位置決定方法において,前記走行手段33を,前記車台30の走行方向前後方向における両端側のそれぞれに一対ずつ設けられた車輪と成すと共に,前記車台30の他端30b側に設けた一対の車輪33c,33dの少なくとも一方を駆動輪とし,前記デッキ10が最下降した状態における前記自走式高所作業車1の平面視で,走行面と各車輪133との接地点a,b,c,dをそれぞれ結ぶ対角線DLの交点xと,前記車台の他端30bにおける走行面と各車輪との接地点c,dの三点により形成される三角形内に前記自走式高所作業車1の重心が入るように,バッテリ34を前記車台の他端側30bにおける前記車台30内に配置することができる(請求項3,10)。 Furthermore, in the self-propelled aerial work vehicle 1 having the above-described configuration and the battery mounting position determination method in the work vehicle, a pair of the traveling means 33 is provided on each of both end sides of the chassis 30 in the front-rear direction. And at least one of a pair of wheels 33c, 33d provided on the other end 30b side of the chassis 30 as drive wheels, and the self-propelled aerial work vehicle 1 in the state where the deck 10 is lowered to the lowest level. In plan view , intersection points x of diagonal lines DL connecting the ground points a, b, c and d between the running surface and the wheels 133, and the ground points c and d between the running surface and the wheels at the other end 30b of the chassis. as the center of gravity of the self-propelled aerial 1 falls within the triangle formed by the three points, it is possible to place the battery 34 to the chassis 30 at the other end 30b of the undercarriage (claim , 10).

更に,前記デッキ10の最上昇時における前記高所作業車1の平面視における重心GH,GHS〔図2(A),図4(A)参照〕が,前記対角線DLの交点xに近接させる位置となるよう前記バッテリ34を配置することが好ましい(請求項4,請求項11)。 Furthermore, the center of gravity G H in a plan view of the aerial 1 at the uppermost of the deck 10, G HS [FIG. 2 (A), the FIG. 4 (A) see] it is close to the intersection x of the diagonal DL so that the position to be, it is preferable to dispose the battery 34 (claim 4, claim 11).

上記のバッテリ34の配置としては,前記車台30の他端30b側に設けられた前記車輪33c,33d間において,前記バッテリ34を前記車台30内に配置するものとすることができる(請求項5)。   The battery 34 may be arranged in the chassis 30 between the wheels 33c and 33d provided on the other end 30b side of the chassis 30 (Claim 5). ).

この場合,前記車台30の一端30a側でバッテリ34に隣接してモータ35を前記車台30内に配置すると共,該モータ35と前記駆動輪(図示の例では車輪33d)とをチェーンとスプロケット,プーリとプーリベルト等の動力伝達手段を介して連結するものとしても良い(請求項6)。 In this case, the motor 35 is adjacent to the battery 34 at one end 30a side of the chassis 30 on the co-when disposed in the chassis 30, (wheel 33d in the illustrated example) the driving wheel with the motor 35 and a chain and sprocket The pulleys may be connected via power transmission means such as a pulley belt (Claim 6).

更に,上記構成の自走式高所作業車1において,前記車台30の一端30a側に配置した一対の車輪33a,33bを操舵可能に構成すると共に,前記車台30の他端30b側に配置した一対の車輪33c,33dを非操舵に構成するものとしても良い(請求項7)。   Further, in the self-propelled aerial work vehicle 1 having the above-described configuration, the pair of wheels 33a and 33b disposed on the one end 30a side of the chassis 30 is configured to be steerable and disposed on the other end 30b side of the chassis 30. The pair of wheels 33c and 33d may be configured to be non-steered (claim 7).

なお,前記デッキ10の前記一端10aを延長する方向に前記デッキ10の床面〔図示の例では第2床面12b:図3(B),図4(B)参照〕がスライドして迫り出し可能に構成するものとしても良い(請求項8)。   In addition, the floor surface of the deck 10 (see the second floor surface 12b in the example shown in FIGS. 3B and 4B) slides in the direction in which the one end 10a of the deck 10 extends. It is good also as what can be comprised (Claim 8).

以上説明したようにバッテリ34を配置した本発明の自走式高所作業車1によれば,デッキ10の昇降機構としてシザースリンク機構20を採用した場合であって,且つ,デッキ10を上昇させた状態においても,自走式高所作業車1の重心が車台30の一端30a側に大きく偏ることを防止でき,その結果,カウンタウエイト等を使用することなしに,又はカウンタウエイトの重量を減らした場合であっても自走式高所作業車1の安定性が向上して安全であると共に,車重が減少された自走式高所作業車1を提供することができた。   As described above, according to the self-propelled aerial work vehicle 1 of the present invention in which the battery 34 is disposed, the scissor link mechanism 20 is employed as the lifting mechanism of the deck 10 and the deck 10 is raised. Even in such a state, it is possible to prevent the center of gravity of the self-propelled aerial work vehicle 1 from being greatly biased toward the one end 30a side of the chassis 30, and as a result, the weight of the counterweight can be reduced without using a counterweight or the like. Even in this case, the stability of the self-propelled aerial work vehicle 1 is improved and safe, and the self-propelled aerial work vehicle 1 with reduced vehicle weight can be provided.

しかも,車台30に設けられた走行手段が,車台30の走行方向前後方向における両端30a,30b側にそれぞれ一対ずつ設けられた車輪33a〜33dである場合,車台30の他端30b側に設けられた車輪33c,33dの少なくとも一方(図示の実施形態では33d)を駆動輪とすることで,デッキ10の下降時における重心GL,GLSが,駆動輪を設けた車台30の他端30b側に偏ったものとなるために,駆動輪33dに対する荷重が増大して,走行面の起伏や凹凸等によっても駆動輪33dが走行面より浮き上がり難く,駆動輪33dがスリップ等することを好適に防止して走行面に対する駆動輪の駆動力を確実に伝達させることができた。 In addition, when the traveling means provided in the chassis 30 is a pair of wheels 33a to 33d provided at both ends 30a and 30b in the longitudinal direction of the chassis 30, respectively, the traveling means is provided on the other end 30b side of the chassis 30. By using at least one of the wheels 33c and 33d (33d in the illustrated embodiment) as a driving wheel, the center of gravity G L and G LS when the deck 10 is lowered is on the other end 30b side of the chassis 30 provided with the driving wheel. Therefore, the load on the driving wheel 33d is increased, and the driving wheel 33d is not easily lifted from the traveling surface due to undulations or irregularities on the traveling surface, and the driving wheel 33d is preferably prevented from slipping. As a result, the driving force of the driving wheel against the traveling surface can be reliably transmitted.

更にデッキ10の最上昇時における前記高所作業車1の平面視における重心GH,GHSが,前記対角線DLの交点xに近接するようにバッテリ34を配置することで,デッキ10を上昇した状態で行う高所作業時における自走式高所作業車1の安定性をより一層高めることができた。 Further, the deck 10 is raised by arranging the battery 34 so that the center of gravity G H and G HS in plan view of the aerial work vehicle 1 at the highest rise of the deck 10 is close to the intersection point x of the diagonal line DL. The stability of the self-propelled aerial work vehicle 1 at the time of aerial work performed in a state could be further increased.

車台30に前述したように4つの車輪33(33a〜33d)を設けた構成において,バッテリ34を車台30の他端30b側に設けた車輪33c,33d間に配置した構成にあっては,車台30の他端30b側の側面に開口やこの開口を開閉する開閉扉を設けることで,バッテリ34の引き出し等の作業が容易であり,メンテナンス性にも優れたものとすることができた。 In the configuration in which the four wheels 33 (33a to 33d) are provided in the chassis 30 as described above, the battery 34 is disposed between the wheels 33c and 33d provided on the other end 30b side of the chassis 30. By providing an opening and an opening / closing door for opening and closing the opening on the side surface on the other end 30b side of the battery 30, the operation of drawing out the battery 34 and the like can be easily performed, and the maintainability can be improved.

特に,駆動輪33dを駆動するモータ35を,前記バッテリ34に対し車台30の一端30a側に隣接して設けると共に,このモータ35と駆動輪33dとを,例えばチェーンとスプロケット,プーリとプーリベルト等の動力伝達手段によって連結することにより,モータ35等がバッテリ34の引き出しに際して障害となることを防止することができた。   In particular, a motor 35 for driving the drive wheels 33d is provided adjacent to the battery 34 on the one end 30a side of the chassis 30, and the motor 35 and the drive wheels 33d are provided with, for example, a chain and a sprocket, a pulley and a pulley belt, etc. Thus, it is possible to prevent the motor 35 and the like from being obstructed when the battery 34 is pulled out.

また,車台30の一端30a側に設けた一対の車輪33a,33bを操舵可能に構成すると共に,前記車台30の他端30b側に設けた一対の車輪33c,33d,すなわち駆動輪33dを含む車輪を非操舵としたことで,駆動輪を操舵する場合に必要となる複雑な構造を採用したり,車輪を操舵させるための空間を必要とせず,自走式高所作業車1を操舵可能とすることができ,車輪33c,33dの間の空間を広くすることができることから,比較的大きな容量のバッテリを搭載することができた。   Further, the pair of wheels 33a and 33b provided on the one end 30a side of the chassis 30 is configured to be steerable, and the wheel including the pair of wheels 33c and 33d provided on the other end 30b side of the chassis 30, that is, the drive wheels 33d. By adopting non-steering, it is possible to steer the self-propelled aerial work vehicle 1 without adopting a complicated structure that is necessary when steering the drive wheels or requiring a space for steering the wheels. Since the space between the wheels 33c and 33d can be widened, a battery having a relatively large capacity can be mounted.

更に,前述したバッテリ34の配置により,前記車台30の一端30a側と同一側である前記デッキ10の一端10a側において床面(第2床面12b)を前方にスライドさせて迫り出させることが可能となり,図7を参照して説明したように基礎等が張り出して車台30を近付けることができない壁面等に対する高所作業であっても,デッキ10の迫り出し部分に作業者が搭乗して容易に作業を行うことができると共に,このような構成を採用した場合であっても自走式高所作業車の安定性を高めることができた。   Furthermore, the arrangement of the battery 34 described above allows the floor surface (second floor surface 12b) to slide forward on the one end 10a side of the deck 10 which is the same side as the one end 30a side of the chassis 30. As described with reference to FIG. 7, it is easy for an operator to get on the protruding portion of the deck 10 even when working at a high place on a wall or the like where the foundation or the like overhangs and the chassis 30 cannot be approached. As a result, the stability of the self-propelled aerial work platform could be improved even when this configuration was adopted.

以下,本発明の実施形態につき添付図面を参照しながら詳細に説明する。   Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

図1〜4において,本発明の高所作業車1は,走行手段33(33a〜33d)を有する車台30上にシザースリンク機構からなる昇降機構20を介して昇降するデッキ10を備えている。   1-4, the aerial work vehicle 1 of the present invention includes a deck 10 that moves up and down on a chassis 30 having traveling means 33 (33a to 33d) via an elevating mechanism 20 including a scissor link mechanism.

このデッキ10には防護柵11が設けられる等して,このデッキ10上に搭乗した作業者や荷物等の落下が防止されている。このデッキ10は,図3(B)及び図4(B)に示すようにデッキ10の床面12がスライドしてデッキ10の一端10a側より迫り出す,張り出しデッキ乃至は延長デッキとして構成することもでき,この場合には,デッキ10の床面は,第1床面12a及び第2床面12bの二重に構成する。もっとも,デッキの床12は,図1,図2に示すようにスライドを行わない,固定式のものであっても良い。   The deck 10 is provided with a protective fence 11 and the like, so that an operator, a luggage, etc. boarded on the deck 10 are prevented from falling. As shown in FIGS. 3B and 4B, the deck 10 is configured as an overhanging deck or an extended deck in which the floor surface 12 of the deck 10 slides and protrudes from the one end 10a side of the deck 10. In this case, the floor surface of the deck 10 is constituted by a double of the first floor surface 12a and the second floor surface 12b. However, the deck floor 12 may be a fixed floor that does not slide as shown in FIGS.

なお,図1(B),(C)中の符号13は,デッキ10の一端側10aにおいて防護柵11に取り付けられた操作盤13であり,デッキ10上に搭乗した作業者が,この操作盤13に設けられたスイッチ類を操作することにより,自走式高所作業車1の走行,操舵,デッキ10の昇降の操作を行うことができるように構成されている。   Reference numerals 13 in FIGS. 1B and 1C are an operation panel 13 attached to the protective fence 11 on one end side 10a of the deck 10, and an operator boarded on the deck 10 can use this operation panel. By operating the switches provided at 13, the self-propelled aerial work vehicle 1 can be operated for running, steering, and raising / lowering the deck 10.

昇降機構である前述のシザースリンク機構20は,同一長さのアーム211,212及び221,222をX字状に交叉させ,両アームの交点を枢着して構成された各X字状リンク(21a〜21d,22a〜22d)を一段とし,この各X字状リンク(21a〜21d,22a〜22d)を複数段枢着連結して構成されたX字状リンク機構21,22を,車台30の幅方向における両側(以下,「左右」という。)にそれぞれ設けることにより形成されたものであり〔図2(B),(C)参照〕,図示の実施形態にあっては,左右それぞれのX字状リンク機構21,22を構成する個々のX字状リンクをそれぞれ1段として,計4段(21a〜21d,22a〜22d)を枢着連結して,前述したシザースリンク機構20を構成している。   The above-mentioned scissor link mechanism 20 which is an elevating mechanism has X-shaped links formed by crossing arms 211, 212 and 221, 222 of the same length in an X shape and pivoting the intersections of both arms ( 21a to 21d and 22a to 22d) are arranged in a single stage, and X-shaped link mechanisms 21 and 22 configured by connecting the X-shaped links (21a to 21d and 22a to 22d) in a plurality of stages are connected to a chassis 30. Are formed on both sides in the width direction (hereinafter referred to as “left and right”), respectively (see FIGS. 2B and 2C). In the illustrated embodiment, Each of the X-shaped links constituting the X-shaped link mechanisms 21 and 22 is set to one stage, and a total of four stages (21a to 21d, 22a to 22d) are pivotally connected to form the scissor link mechanism 20 described above. doing.

図2(C)において,このシザースリンク機構20の紙面中央側に配置されたアームをインナーアーム211,221,外側に配置されたアームをアウターアーム212,222として説明すると,各X字状リンク21a〜21d,22a〜22d間の連結は,下段のインナーアーム211,221の上端と,上段のアウターアーム212,222の下端間を,又,下段のアウターアーム212,222の上端と上段のインナーアーム211,221の下端とを交互に連結するように左右のX字状リンク機構21,22がそれぞれ形成されている〔図2(B)参照〕。   In FIG. 2C, the arms disposed on the center side of the scissors link mechanism 20 are described as inner arms 211 and 221 and the arms disposed on the outer side are outer arms 212 and 222. Each X-shaped link 21a 21d and 22a to 22d are connected between the upper ends of the lower inner arms 211 and 221 and the lower ends of the upper outer arms 212 and 222, and the upper ends of the lower outer arms 212 and 222 and the upper inner arm. Left and right X-shaped link mechanisms 21 and 22 are formed so as to alternately connect the lower ends of 211 and 221 [see FIG. 2 (B)].

そして,最下段のX字状リンク21a,22aの一方のアーム(図示の例ではインナーアーム211,221)の下端部を車台30の一端30a側に枢着し,最下段のX字状リンク21aの他方のアーム(図示の例ではアウターアーム212,222)下端部を,前記インナーアーム211,221の枢着位置に対して車台30の他端30b寄りの位置において車台30の長手方向に摺動自在に支持し,さらに,最上段のX字状リンク21d,22dのインナーアーム211,221の上端部をデッキ10の底面にデッキ10の長手方向へ摺動可能に支持すると共に,アウターアーム212,222の上端部を,デッキ10の一端10a側に枢着している。   Then, the lower end portion of one arm (inner arms 211 and 221 in the illustrated example) of the lowermost X-shaped links 21a and 22a is pivotally attached to the one end 30a side of the chassis 30, and the lowermost X-shaped link 21a. Of the other arm (outer arms 212 and 222 in the illustrated example) is slid in the longitudinal direction of the chassis 30 at a position near the other end 30b of the chassis 30 with respect to the pivot position of the inner arms 211 and 221. Further, the upper ends of the inner arms 211, 221 of the uppermost X-shaped links 21d, 22d are supported on the bottom surface of the deck 10 so as to be slidable in the longitudinal direction of the deck 10, and the outer arms 212, The upper end of 222 is pivotally attached to the one end 10 a side of the deck 10.

また,最上段及び最下段の左右のX字状リンク21d,21d及び22a,22aの交点は,両X字状リンクを構成する各アウターアーム212,222及びインナーアーム211,221と共に枢着軸23b,23aで連結されている。   Further, the intersection of the left and right X-shaped links 21d, 21d and 22a, 22a at the uppermost and lowermost stages is the pivot shaft 23b together with the outer arms 212, 222 and the inner arms 211, 221 constituting both X-shaped links. , 23a.

なお,中間段の左右のX字状リンク21b,21c及び22b,22cの交点は,左右それぞれ別々にインナーアームとアウターアームとが枢着軸で連結されている。   In addition, at the intersections of the left and right X-shaped links 21b, 21c and 22b, 22c in the intermediate stage, the inner arm and the outer arm are separately connected to each other by a pivot shaft.

更に,昇降機構20は上下複数段に枢着して連結された左右一対の各X字状リンク21a〜21d,22a〜22dを垂直方向に移動させる油圧シリンダ24を備える。   Further, the lifting mechanism 20 includes a hydraulic cylinder 24 that moves a pair of left and right X-shaped links 21a to 21d and 22a to 22d that are pivotally connected to a plurality of upper and lower stages in the vertical direction.

油圧シリンダ24は,最下段のX字状リンク21a,22aと,中間段のX字状リンク21c,22cにそれぞれ設けられたブラケット25,26間に架設され,前記油圧シリンダ24によってシザースリンク機構20が作動し,デッキ10が水平状態を保って昇降する。   The hydraulic cylinder 24 is installed between the lowermost X-shaped links 21a and 22a and the brackets 25 and 26 provided on the intermediate X-shaped links 21c and 22c, respectively. , And the deck 10 moves up and down while maintaining a horizontal state.

前述のシザースリンク機構20及びデッキ10を搭載する前述の車台30は,図1(B),(C)に示すように,図示の実施形態にあっては,モータ35やバッテリ34等の必要な機器を収容するためのケーシングとして機能する箱型の本体31と,前記本体31上に搭載されたフレーム32とを備え,このフレーム32を介して前述のシザースリンク機構20の下端が,車台30上に取り付けられている。   As shown in FIGS. 1B and 1C, the chassis 30 on which the scissor link mechanism 20 and the deck 10 are mounted has a motor 35, a battery 34, and the like in the illustrated embodiment. A box-shaped main body 31 that functions as a casing for housing equipment and a frame 32 mounted on the main body 31 are provided, and the lower end of the scissor link mechanism 20 is placed on the chassis 30 via the frame 32. Is attached.

このフレーム32の下部に設けられた前述の本体31は,図1(A)に示す平面視において,紙面左右方向に長さ方向を有する長方形に形成されており,この本体31の長さ方向における両端側において,幅方向に突出した車軸に対しそれぞれ走行手段である車輪33(33a〜33d)が取り付けられている。
Body 31. mentioned above provided in the lower portion of the frame 32 in the plan view shown in FIG. 1 (A), are made form a rectangle having a length direction in the left-right directions, the length direction of the main body 31 Wheels 33 (33a to 33d), which are traveling means, are respectively attached to the axles protruding in the width direction.

この車台30の本体31内には,前述したようにバッテリ34や,該バッテリ34からの電力供給によって回転するモータ35,モータ35の回転出力を駆動輪に伝達する動力伝達手段が収容されていると共に,車台30の他端30b側に設けられた一対の車輪33c,33d中の少なくとも一方(図示の例では33d),好ましくは双方に対して,前述のモータ35の回転駆動力が伝達されるよう構成されており,このようにしてモータ35からの動力伝達を受けた車輪33dが駆動輪となる。   In the main body 31 of the chassis 30, as described above, the battery 34, the motor 35 that rotates by supplying power from the battery 34, and the power transmission means that transmits the rotational output of the motor 35 to the drive wheels are housed. At the same time, the rotational driving force of the motor 35 is transmitted to at least one (33d in the illustrated example) of the pair of wheels 33c and 33d provided on the other end 30b side of the chassis 30, preferably both. Thus, the wheel 33d that has received the power transmission from the motor 35 in this manner serves as a drive wheel.

車台30の一端30a側に設けられた一対の車輪33a,33bは,本実施形態にあってはこれをフリーホイール(非駆動)とすると共に,この一対の車輪33a,33bを操舵輪と成し,前述した操作盤13による操作によってその舵角を制御可能とすることで,自走式高所作業車1を所望の方向に向けて走行させることができるよう構成している。   In this embodiment, the pair of wheels 33a and 33b provided on the one end 30a side of the chassis 30 is a free wheel (non-driven), and the pair of wheels 33a and 33b are formed as steering wheels. By making the rudder angle controllable by the operation using the operation panel 13 described above, the self-propelled aerial work vehicle 1 can be driven in a desired direction.

このように構成された車台30に対するバッテリ34の配置は,図1(A),(B)に示すように車台30の他端30b側において車台30の前記本体31内に収容されており,図示の実施形態にあっては,図1(A)に示す平面視において,走行面と車輪との接地点a,b,c,dを結ぶ対角線DLの交点xと,車台30の他端30bに配置した一対の車輪の接地点c,dを直線で結んだ三角形を想定し,前述したデッキ10が最下降した時における重心GL〔デッキ10がスライドする第2床面12bを備える図3に示す構成にあっては,第2床面12bを迫り出させた状態における重心GLSを含む;図3(A)参照〕がこの想定された三角形x,c,d内に位置するように構成されている。 As shown in FIGS. 1A and 1B, the battery 34 is disposed in the main body 31 of the chassis 30 on the other end 30b side of the chassis 30 as shown in FIGS. 1A, in the plan view shown in FIG. 1A, the intersection point x of the diagonal line DL connecting the ground contact points a, b, c and d between the running surface and the wheel and the other end 30b of the chassis 30 Assuming a triangle formed by connecting the ground contact points c and d of a pair of wheels with a straight line, the center of gravity G L when the above-described deck 10 descends to the lowest level [Fig. 3 includes a second floor 12b on which the deck 10 slides. in the configuration shown, including the center of gravity G LS in state where the Seridasa the second floor surface 12b; configured FIG 3 (a) see] is located this assumption triangle x, c, in the d Has been.

このようなバッテリ34の配置として,図示の実施形態にあっては,バッテリ34を,車台30の他端30b側に設けられた一対の車輪33c,33d間において前述の車台30の本体31内に収容するものとし,好ましくはバッテリの重心を前記三角形x,c,d内に位置するよう構成している。   In the illustrated embodiment, the battery 34 is disposed in the main body 31 of the chassis 30 between the pair of wheels 33c and 33d provided on the other end 30b side of the chassis 30. The battery is preferably configured so that the center of gravity of the battery is located within the triangle x, c, d.

自走式高所作業車1の走行は,転倒の危険を回避するために一般にデッキ10が最下降した状態において可能となるように構成されるが,このようにデッキ10の最下降時における重心GL,GLSが前述した三角形x,c,d内に配置されることにより,自走式高所作業車1の走行時において車台30の他端30b側,即ち駆動輪33d側に対する車重の配分が大きなものとなる。 In general, the self-propelled aerial work vehicle 1 is configured to be able to run when the deck 10 is in the lowest position in order to avoid the danger of falling. By arranging G L and G LS in the triangles x, c and d described above, the vehicle weight relative to the other end 30b side of the chassis 30, that is, the drive wheel 33d side when the self-propelled aerial work vehicle 1 is traveling. The distribution of is large.

その結果,駆動輪33dが路面や床面等の走行面に対して押しつけられることとなり,スリップ等を生じることなくモータ35からの駆動力が駆動輪33dを介して確実に走行面に対して伝達されると共に,例えば走行面に凹凸が存在することにより4輪中の3輪しか接地していない状態が生じた場合であっても,車台30の他端30b側に設けられた,駆動輪33dを含む2輪33c,33dは走行面に対して接触した状態が維持されるために,駆動輪33dが走行面より離間して空転等することが防止される。   As a result, the driving wheel 33d is pressed against the traveling surface such as a road surface or a floor surface, and the driving force from the motor 35 is reliably transmitted to the traveling surface via the driving wheel 33d without causing a slip or the like. At the same time, for example, even when a state where only three of the four wheels are grounded due to unevenness on the running surface occurs, the drive wheel 33d provided on the other end 30b side of the chassis 30 is provided. Since the two wheels 33c and 33d including are maintained in contact with the traveling surface, the drive wheels 33d are prevented from idling away from the traveling surface.

更に,このようにデッキ10の最下降時における重心GL,GLSが前述した三角形x,c,d内となるようにしたバッテリ34の配置により,デッキ10を最上昇時における重心GH〔図2(A)参照〕,更にこのデッキ10の床面をスライドさせて迫り出させた際の重心GHS〔図4(A)参照〕を,前述した対角線DLの交点xに近付けることができ,高所作業中における自走式高所作業車1の安定性が増し,転倒等の危険性を大幅に減少させることが可能である。 Further, by arranging the battery 34 so that the center of gravity G L , G LS when the deck 10 is at the lowest position falls within the above-described triangles x, c, d, the center of gravity G H when the deck 10 is at the highest position [ Further, the center of gravity G HS when the floor of the deck 10 is slid and pushed out (see FIG. 4A) can be brought closer to the intersection point x of the diagonal line DL described above. Thus, the stability of the self-propelled aerial work vehicle 1 during the aerial work can be increased, and the risk of falling or the like can be greatly reduced.

一例として,図示の実施形態に示した自走式高所作業車1は,デッキ10の床面高を地上高で最大4m迄上昇可能としたもので,バッテリ34を含めた全重量が550kg程度と,比較的小型の部類に属する自走式高所作業車1である。   As an example, the self-propelled aerial work vehicle 1 shown in the illustrated embodiment is capable of raising the floor height of the deck 10 to a maximum of 4 m above the ground, and the total weight including the battery 34 is about 550 kg. The self-propelled aerial work vehicle 1 belongs to a relatively small category.

この自走式高所作業車1の重量内訳は,デッキ10の重量が約50kg,シザースリンク機構20の重量が約200kg,車台30の重量が約300kg程度であり,このうち車台30に5時間率容量で100(Ah)程度のバッテリ34を2機搭載した場合,車台30の重量300kgのうちバッテリ34の重量だけで約70〜80kg程度,すなわち車台30の重量の約1/4程度を占めるものとなる。   The weight breakdown of the self-propelled aerial work vehicle 1 is that the weight of the deck 10 is about 50 kg, the weight of the scissor link mechanism 20 is about 200 kg, and the weight of the chassis 30 is about 300 kg. When two batteries 34 having a capacity of about 100 (Ah) are mounted, the weight of the battery 34 alone is about 70 to 80 kg out of the weight of the chassis 30, that is, about 1/4 of the weight of the chassis 30. It will be a thing.

従って,車台30内におけるバッテリ34を最適な位置に配置することにより,カウンタウエイト等を設けることなく自走式高所作業車1の重心GL,GLS,GH,GHSの位置を高所作業時における安定性に優れ,かつ,デッキ10を下降した状態で行われる走行時において駆動輪の駆動力を確実に走行面に伝達し得る位置に調整することが可能であり,図示のバッテリ34の配置によれば,図2(A)に示すようにデッキ10が最上昇した状態(但し,床面が迫り出していない状態)においても平面視における重心GHは前述した三角形x,c,d内にあると共に,対角線DLの交点xに近接した位置にあり,更に,デッキ10を最上昇させた状態で更にデッキ10の床面を迫り出させた図4(B)に示す状態においても,図4(A)に示すように平面視における重心GHSは,対角線DLの交点xに近接した位置にあり,いずれの状態においても自走式高所作業車1は安定した状態にある。 Therefore, by arranging the battery 34 in the chassis 30 at the optimum position, the position of the center of gravity G L , G LS , G H , G HS of the self-propelled aerial work vehicle 1 is increased without providing a counterweight or the like. The battery shown in the figure can be adjusted to a position where the driving force of the driving wheels can be reliably transmitted to the running surface when traveling with the deck 10 being lowered and having excellent stability during work. According to the arrangement 34, the center of gravity GH in plan view is equal to the triangles x and c described above even when the deck 10 is at its highest position (however, the floor surface is not protruding) as shown in FIG. , D, and close to the intersection point x of the diagonal line DL. Further, in the state shown in FIG. Is also shown in FIG. The center of gravity G HS in plan view as is located at a position close to the intersection x of the diagonal lines DL, self-propelled aerial platforms 1 in either state in a stable state.

なお,上記のバッテリ34の配置において,駆動輪33dを駆動するモータ35は,車台30の幅方向に出力軸の軸芯方向を向けた状態で,前記バッテリ34に対して車台30の一端30a側に近接配置されており,このモータ35の出力軸と,車台30の他端30b側に設けた車輪33c,33dの一方33dとを,スプロケットとチェーン,プーリとプーリベルト,その他の動力伝達機構(本実施形態にあっては,詳細な図示は省略するがスプロケットとチェーン)により連結して,駆動輪33dを駆動可能に構成している。   In the arrangement of the battery 34 described above, the motor 35 for driving the drive wheels 33d is located on the one end 30a side of the chassis 30 with respect to the battery 34 in a state where the axial direction of the output shaft is oriented in the width direction of the chassis 30. The output shaft of the motor 35 and one of the wheels 33c and 33d 33d provided on the other end 30b side of the chassis 30 are connected to a sprocket and a chain, a pulley and a pulley belt, and other power transmission mechanisms ( In the present embodiment, although not shown in detail, the drive wheel 33d is configured to be driven by being connected by a sprocket and a chain).

このモータ35の配置により,前記バッテリ34を収容した車台30の他端30b側における本体31の側面に開口を設け,また,必要に応じてこの開口を開閉する開閉扉を設けることにより,この開閉扉の開放によって現れた開口を介して本体31内に収容されたバッテリ34を引き出し可能に構成する場合等において,前述したモータ35や動力伝達手段がバッテリ34の引き出し等に際して干渉することがなく,バッテリ34の保守点検作業等を容易なものとすることができる。   With the arrangement of the motor 35, an opening is provided in the side surface of the main body 31 on the other end 30b side of the chassis 30 housing the battery 34, and an opening / closing door for opening and closing the opening is provided as necessary. In the case where the battery 34 accommodated in the main body 31 can be pulled out through the opening that appears when the door is opened, the above-described motor 35 and power transmission means do not interfere when the battery 34 is pulled out. Maintenance and inspection work of the battery 34 can be facilitated.

本発明の自走式高所作業車(デッキ下降時)の図であり,(A)は平面図(但し,車台部分のみ),(B)は正面図,(C)は右側面図。BRIEF DESCRIPTION OF THE DRAWINGS It is a figure of the self-propelled aerial work vehicle (deck descending) of this invention, (A) is a top view (however, only a chassis part), (B) is a front view, (C) is a right view. 本発明の自走式高所作業車(デッキ上昇時)の図であり,(A)は平面図(但し,車台部分のみ),(B)は正面図,(C)は右側面図。BRIEF DESCRIPTION OF THE DRAWINGS It is a figure of the self-propelled aerial work vehicle (deck rise) of this invention, (A) is a top view (however, only a chassis part), (B) is a front view, (C) is a right view. 本発明の別の自走式高所作業車(デッキ下降時)の図であり,(A)は平面図(但し,車台部分のみ),(B)は正面図,(C)は右側面図。It is a figure of another self-propelled aerial work vehicle (deck descending) of this invention, (A) is a top view (however, only a chassis part), (B) is a front view, (C) is a right view. . 本発明の別の自走式高所作業車(デッキ上昇時)の図であり,(A)は平面図(但し,車台部分のみ),(B)は正面図,(C)は右側面図。It is a figure of another self-propelled aerial work vehicle (at the time of deck raising) of the present invention, (A) is a top view (however, only a chassis part), (B) is a front view, (C) is a right view. . バッテリを車台中央に配置した本願の構成を備えない自走式高所作業車(デッキ下降時)の図であり,(A)は平面図(但し,車台部分のみ),(B)は正面図,(C)は右側面図。It is a figure of a self-propelled aerial work vehicle (when the deck is lowered) that does not have the configuration of the present application in which the battery is arranged at the center of the chassis, (A) is a plan view (however, only the chassis part), and (B) is a front view. , (C) is a right side view. バッテリを車台中央に配置した本願の構成を備えない自走式高所作業車(デッキ上昇時)の図であり,(A)は平面図(但し,車台部分のみ),(B)は正面図,(C)は右側面図。It is a figure of a self-propelled aerial work vehicle (when the deck is raised) that does not have the configuration of the present application in which the battery is arranged in the center of the chassis, (A) is a plan view (however, only the chassis part), (B) is a front view , (C) is a right side view. 建築物等の基礎等が張り出している作業現場における自走式高所作業車の配置状況を示す概略図。Schematic which shows the arrangement | positioning condition of the self-propelled aerial work vehicle in the work site where the foundations, such as a building, overhang.

符号の説明Explanation of symbols

1 自走式高所作業車
10 デッキ
10a 一端(デッキ10の)
10b 他端(デッキ10の)
11 防護柵
12 床面
12a 第1床面
12b 第2床面
13 操作盤
20 昇降機構(シザースリンク機構)
21,22 X字状リンク機構(左右)
21a〜21d,22a〜22d X字状リンク
211,221 アームの一方(インナーアーム)
212,222 アームの他方(アウターアーム)
23a,23b 枢着軸
24 油圧シリンダ
25,26 ブラケット(油圧シリンダの取付用)
30 車台
30a 一端(車台30の)
30b 他端(車台30の)
31 本体
32 フレーム
33(33a〜33d) 走行手段(車輪)
34 バッテリ
35 モータ
DL 対角線
x 対角線DLの交点
a〜d 平面視における車台の角部
L 自走式高所作業車の重心(デッキ下降,床面の迫り出し無し)
LS 自走式高所作業車の重心(デッキ下降,床面迫り出し)
H 自走式高所作業車の重心(デッキ上昇,床面の迫り出し無し)
HS 自走式高所作業車の重心(デッキ上昇,床面迫り出し)
100 自走式高所作業車
110 デッキ
110a 一端(デッキ110の)
110b 他端(デッキ110の)
113 操作盤
120 昇降機構(シザースリンク機構)
121a X字状リンク(最下段)
121’ 一方のアーム(インナーアーム)
121’’ 他方のアーム(アウターアーム)
130 車台
130a 一端(車台130の)
130b 他端(車台130の)
133 走行手段(車輪)
134 バッテリ
150 カウンタウエイト
1 self-propelled aerial work platform 10 deck 10a one end (of deck 10)
10b The other end (of deck 10)
DESCRIPTION OF SYMBOLS 11 Guard fence 12 Floor surface 12a 1st floor surface 12b 2nd floor surface 13 Control panel 20 Lifting mechanism (scissors link mechanism)
21, 22 X-shaped link mechanism (left and right)
21a-21d, 22a-22d X-shaped link 211, 221 One of the arms (inner arm)
212, 222 The other arm (outer arm)
23a, 23b Pivoting shaft 24 Hydraulic cylinder 25, 26 Bracket (for mounting hydraulic cylinder)
30 chassis 30a one end (of chassis 30)
30b The other end (of the chassis 30)
31 Main body 32 Frame 33 (33a to 33d) Traveling means (wheel)
34 Battery 35 Motor DL Diagonal line x Diagonal line intersections a to d Corner of the chassis in plan view GL Center of gravity of the self-propelled aerial work platform (no deck descending, no floor surface protruding)
G LS Self-propelled aerial work platform center of gravity (deck descending, floor approaching)
Center of gravity of GH self-propelled aerial work platform (deck lift, no floor bulge)
Center of gravity of G HS self-propelled aerial work platform (deck lift, floor surface approach)
100 Self-propelled aerial work platform 110 Deck 110a One end (of deck 110)
110b The other end (of deck 110)
113 Control panel 120 Elevating mechanism (scissors link mechanism)
121a X-shaped link (bottom level)
121 'One arm (inner arm)
121 '' other arm (outer arm)
130 chassis 130a one end (of chassis 130)
130b The other end (of chassis 130)
133 Traveling means (wheels)
134 Battery 150 Counterweight

Claims (11)

走行手段を備えた車台と,前記車台上で昇降するデッキと,前記車台と前記デッキ間に配置されて前記デッキを昇降させる複数段のX字状リンクによって構成されたシザースリンク機構を備え,前記シザースリンク機構の最下段におけるX字状リンクを構成する一方のアーム下端を前記車台の走行方向前後方向におけるいずれか一端寄りに枢着すると共に,他方のアームの下端を,車台上に摺動可能に取り付け,更に,前記シザースリンク機構の最上段におけるX字状リンクを構成する一方のアームの上端を前記デッキの底部に摺動可能に取り付けると共に,他方のアームの上端を,前記車台の一端と同一方向の一端寄りで前記デッキの底部に枢着した自走式高所作業車において,
前記デッキが最下降した状態における前記自走式高所作業車の平面視で,平面矩形状の前記車台の各角部の対角線の交点と,前記車台の他端における角部の三点により形成される三角形内に前記自走式高所作業車の重心が入るように,バッテリを前記車台の他端側における前記車台内に配置したことを特徴とする自走式高所作業車。
A scissor link mechanism comprising a chassis having traveling means; a deck that moves up and down on the chassis; and a plurality of X-shaped links that are arranged between the chassis and the deck to raise and lower the deck, The lower end of one arm that forms the X-shaped link at the bottom of the scissor link mechanism can be pivotally attached to one end in the longitudinal direction of the chassis, and the lower end of the other arm can slide on the chassis The upper end of one arm constituting the X-shaped link in the uppermost stage of the scissor link mechanism is slidably attached to the bottom of the deck, and the upper end of the other arm is connected to one end of the chassis. In a self-propelled aerial work platform pivoted to the bottom of the deck near one end in the same direction,
In plan view of the self-propelled aerial work vehicle with the deck lowered to the bottom, formed by three intersections of diagonal lines at each corner of the chassis having a rectangular plane and a corner at the other end of the chassis A self-propelled aerial work vehicle, characterized in that a battery is disposed in the chassis on the other end side of the chassis so that the center of gravity of the self-propelled aerial work vehicle enters a triangle.
前記走行手段を前記車台の走行方向前後方向における両端側のそれぞれに一対ずつ設けられた車輪と成すと共に,
前記車台の他端側に設けた一対の車輪の少なくとも一方を駆動輪としたことを特徴とする請求項1記載の自走式高所作業車。
The traveling means comprises a pair of wheels provided on each of both end sides in the longitudinal direction of the chassis,
The self-propelled aerial work vehicle according to claim 1, wherein at least one of a pair of wheels provided on the other end side of the chassis is a drive wheel.
走行手段を備えた車台と,前記車台上で昇降するデッキと,前記車台と前記デッキ間に配置されて前記デッキを昇降させる複数段のX字状リンクによって構成されたシザースリンク機構を備え,前記シザースリンク機構の最下段におけるX字状リンクを構成する一方のアーム下端を前記車台の走行方向前後方向におけるいずれか一端寄りに枢着すると共に,他方のアームの下端を,車台上に摺動可能に取り付け,更に,前記シザースリンク機構の最上段におけるX字状リンクを構成する一方のアームの上端を前記デッキの底部に摺動可能に取り付けると共に,他方のアームの上端を,前記車台の一端と同一方向の一端寄りで前記デッキの底部に枢着した自走式高所作業車において,
前記走行手段を前記車台の走行方向前後方向における両端側のそれぞれに一対ずつ設けられた車輪と成すと共に,
前記車台の他端側に設けた一対の車輪の少なくとも一方を駆動輪とし,
前記デッキが最下降した状態における前記自走式高所作業車の平面視で,走行面と各車輪との接地点をそれぞれ結ぶ対角線の交点と,前記車台の他端における走行面と各車輪との接地点の三点により形成される三角形内に前記自走式高所作業車の重心が入るように,バッテリを前記車台の他端側における前記車台内に配置したことを特徴とする自走式高所作業車。
A scissor link mechanism comprising a chassis having traveling means; a deck that moves up and down on the chassis; and a plurality of X-shaped links that are arranged between the chassis and the deck to raise and lower the deck, The lower end of one arm that forms the X-shaped link at the bottom of the scissor link mechanism can be pivotally attached to one end in the longitudinal direction of the chassis, and the lower end of the other arm can slide on the chassis The upper end of one arm constituting the X-shaped link in the uppermost stage of the scissor link mechanism is slidably attached to the bottom of the deck, and the upper end of the other arm is connected to one end of the chassis. In a self-propelled aerial work platform pivoted to the bottom of the deck near one end in the same direction,
The traveling means comprises a pair of wheels provided on each of both end sides in the longitudinal direction of the chassis,
At least one of a pair of wheels provided on the other end side of the chassis is a drive wheel,
In a plan view of the self-propelled aerial work vehicle in the state where the deck is lowered, an intersection of diagonal lines respectively connecting a grounding point between the traveling surface and each wheel , a traveling surface and each wheel at the other end of the chassis, A battery is disposed in the chassis on the other end side of the chassis so that the center of gravity of the self-propelled aerial work vehicle enters a triangle formed by three ground contact points. Type aerial work vehicle.
前記デッキの最上昇時における前記高所作業車の平面視における重心が,前記対角線の交点に近接した位置となるように,前記バッテリを配置したことを特徴とする請求項1〜3いずれか1項記載の自走式高所作業車。 4. The battery according to claim 1 , wherein the battery is arranged such that a center of gravity of the aerial work vehicle in a plan view when the deck is at the highest position is close to an intersection of the diagonal lines. The self-propelled aerial work vehicle described in the section. 前記車台の他端側に設けられた前記車輪間において,前記バッテリを前記車台内に配置したことを特徴とする請求項2又は3記載の自走式高所作業車。   The self-propelled aerial work vehicle according to claim 2 or 3, wherein the battery is disposed in the chassis between the wheels provided on the other end side of the chassis. 前記車台の一端側で前記バッテリに隣接してモータを前記車台内に配置すると共に,該モータと前記駆動輪とを動力伝達手段を介して連結したことを特徴とする請求項5記載の自走式高所作業車。   6. A self-propelled vehicle according to claim 5, wherein a motor is disposed in the chassis adjacent to the battery on one end side of the chassis, and the motor and the driving wheel are connected via a power transmission means. Type aerial work vehicle. 前記車台の一端側に配置した一対の車輪を操舵可能に構成すると共に,前記車台の他端側に配置した一対の車輪を非操舵に構成したことを特徴とする請求項2,3,5又は6記載の自走式高所作業車。   The pair of wheels arranged on one end side of the chassis is configured to be steerable, and the pair of wheels arranged on the other end side of the chassis is configured to be non-steered. 6. The self-propelled aerial work vehicle described in 6. 前記デッキの前記一端を延長する方向に前記デッキがスライドして迫り出し可能に構成されていることを特徴とする請求項1〜7いずれか1項記載の自走式高所作業車。   The self-propelled aerial work vehicle according to any one of claims 1 to 7, wherein the deck slides in a direction in which the one end of the deck extends and can be pushed out. 走行手段を備えた車台と,前記車台上で昇降するデッキと,前記車台と前記デッキ間に配置されて前記デッキを昇降させる複数段のX字状リンクによって構成されたシザースリンク機構を備え,前記シザースリンク機構の最下段におけるX字状リンクを構成する一方のアーム下端を前記車台の走行方向前後方向におけるいずれか一端寄りに枢着すると共に,他方のアームの下端を,車台上に摺動可能に取り付け,更に,前記シザースリンク機構の最上段におけるX字状リンクを構成する一方のアームの上端を前記デッキの底部に摺動可能に取り付けると共に,他方のアームの上端を,前記車台の一端と同一方向の一端寄りで前記デッキの底部に枢着した自走式高所作業車において,
前記デッキが最下降した状態における前記自走式高所作業車の平面視で,平面矩形状の前記車台の各角部の対角線の交点と,前記車台の他端における角部の三点により形成される三角形内に,前記自走式高所作業車の重心が入るように,バッテリを前記車台の他端側における前記車台内に配置することを特徴とする自走式高所作業車におけるバッテリの搭載位置決定方法。
A scissor link mechanism comprising a chassis having traveling means; a deck that moves up and down on the chassis; and a plurality of X-shaped links that are arranged between the chassis and the deck to raise and lower the deck, The lower end of one arm that forms the X-shaped link at the bottom of the scissor link mechanism can be pivotally attached to one end in the longitudinal direction of the chassis, and the lower end of the other arm can slide on the chassis The upper end of one arm constituting the X-shaped link in the uppermost stage of the scissor link mechanism is slidably attached to the bottom of the deck, and the upper end of the other arm is connected to one end of the chassis. In a self-propelled aerial work platform pivoted to the bottom of the deck near one end in the same direction,
In plan view of the self-propelled aerial work vehicle with the deck lowered to the bottom, formed by three intersections of diagonal lines at each corner of the chassis having a rectangular plane and a corner at the other end of the chassis The battery in the self-propelled aerial work vehicle is characterized in that a battery is disposed in the chassis on the other end side of the chassis so that the center of gravity of the self-propelled aerial work vehicle enters the triangle. Mounting position determination method.
走行手段を備えた車台と,前記車台上で昇降するデッキと,前記車台と前記デッキ間に配置されて前記デッキを昇降させる複数段のX字状リンクによって構成されたシザースリンク機構を備え,前記シザースリンク機構の最下段におけるX字状リンクを構成する一方のアーム下端を前記車台の走行方向前後方向におけるいずれか一端寄りに枢着すると共に,他方のアームの下端を,車台上に摺動可能に取り付け,更に,前記シザースリンク機構の最上段におけるX字状リンクを構成する一方のアームの上端を前記デッキの底部に摺動可能に取り付けると共に,他方のアームの上端を,前記車台の一端と同一方向の一端寄りで前記デッキの底部に枢着した自走式高所作業車において,
前記走行手段を前記車台の走行方向前後方向における両端側のそれぞれに一対ずつ設けられた車輪と成すと共に,
前記車台の他端側に設けた一対の車輪の少なくとも一方を駆動輪とし,
前記デッキが最下降した状態における前記自走式高所作業車の平面視で,走行面と各車輪との接地点をそれぞれ結ぶ対角線の交点と,前記車台の他端における走行面と各車輪との接地点の三点により形成される三角形内に前記自走式高所作業車の重心が入るように,バッテリを前記車台の他端側における前記車台内に配置することを特徴とする自走式高所作業車におけるバッテリの搭載位置決定方法。
A scissor link mechanism comprising a chassis having traveling means; a deck that moves up and down on the chassis; and a plurality of X-shaped links that are arranged between the chassis and the deck to raise and lower the deck, The lower end of one arm that forms the X-shaped link at the bottom of the scissor link mechanism can be pivotally attached to one end in the longitudinal direction of the chassis, and the lower end of the other arm can slide on the chassis The upper end of one arm constituting the X-shaped link in the uppermost stage of the scissor link mechanism is slidably attached to the bottom of the deck, and the upper end of the other arm is connected to one end of the chassis. In a self-propelled aerial work platform pivoted to the bottom of the deck near one end in the same direction,
The traveling means comprises a pair of wheels provided on each of both end sides in the longitudinal direction of the chassis,
At least one of a pair of wheels provided on the other end side of the chassis is a drive wheel,
In a plan view of the self-propelled aerial work vehicle in the state where the deck is lowered, an intersection of diagonal lines respectively connecting a grounding point between the traveling surface and each wheel , a traveling surface and each wheel at the other end of the chassis, A battery is disposed in the chassis on the other end side of the chassis so that the center of gravity of the self-propelled aerial work vehicle enters a triangle formed by three ground contact points. A method for determining the battery mounting position in an aerial work platform.
前記デッキの最上昇時における前記高所作業車の平面視における重心が,前記対角線の交点に近接するように,前記車台の他端側に前記バッテリを搭載することを特徴とする請求項9又は10記載の自走式高所作業車におけるバッテリの搭載位置決定方法。   10. The battery is mounted on the other end side of the chassis such that the center of gravity of the aerial work vehicle when viewed from the top when the deck is at the highest position is close to the intersection of the diagonal lines. The battery mounting position determination method in the self-propelled aerial work vehicle according to 10.
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