JP2006290583A - Parts feeder and its driving method - Google Patents

Parts feeder and its driving method Download PDF

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JP2006290583A
JP2006290583A JP2005115721A JP2005115721A JP2006290583A JP 2006290583 A JP2006290583 A JP 2006290583A JP 2005115721 A JP2005115721 A JP 2005115721A JP 2005115721 A JP2005115721 A JP 2005115721A JP 2006290583 A JP2006290583 A JP 2006290583A
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base plate
vibration
piezoelectric element
vibration excitation
pair
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JP4084368B2 (en
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Hiroshi Nakayama
博 中山
Katsuto Hamai
克人 浜井
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Sanki Co Ltd
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Sanki Co Ltd
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Abstract

<P>PROBLEM TO BE SOLVED: To allow application to a small number of piezoelectric elements, which can serve as driving sources and can be conveyed in multiple lines, for performing efficient drive and easily adjusting a driving condition of each piezoelectric element by a simple and easily handleable configuration. <P>SOLUTION: Between a plurality of top plates 23 and 36, which can be conveyed in multiple lines, and a common base plate 22, a pair of vibration excitation members 26 and 37 connected vertically via the piezoelectric elements 24a and 24b and amplifying springs 25a and 25b are arranged respectively. The base plate 22, on which the lower ends of the vibration excitation members 26 and 37 are fixed and supported, is installed on an installation face via a spring member 41. When either of a pair of piezoelectric elements 24a and 24b is used as the drive source, conveyance in multiple lines can be carried out. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

本発明は、圧電素子を利用して振動を励起し、双方向搬送等の多列搬送を可能とするパーツフィ−ダとその駆動方法に関する。   The present invention relates to a parts feeder that uses a piezoelectric element to excite vibration and enables multi-row conveyance such as bidirectional conveyance, and a driving method thereof.

従来、各種分野における自動組立工程において、チップ抵抗等の電子部品、樹脂成形部品、機械部品などの小物ワークをはじめ、粉末体を搬送供給するためのフィーダにあっては、その駆動源として圧電セラミックス素子を用いた圧電型フィーダ、および電磁石を駆動源とするフィーダがよく知られている。しかるに、前者の圧電型フィーダは、後者の電磁型フィーダと比較して、物品の搬送がスムーズで、消費電力が小さく、また金属性の搬送品に対し着磁するおそれがないなどの特長があり、近年広く普及している(例えば、特許文献1参照)。   Conventionally, in automatic assembly processes in various fields, piezoelectric ceramics are used as a drive source for feeders for conveying and supplying small workpieces such as electronic parts such as chip resistors, resin molded parts, and machine parts. Piezoelectric feeders using elements and feeders using electromagnets as driving sources are well known. However, the former piezoelectric feeder has features such as smoother article transportation, lower power consumption, and no possibility of being magnetized on metallic carriages compared to the latter electromagnetic feeder. In recent years, it has become widespread (see, for example, Patent Document 1).

ところが、微細なチップ抵抗やチップコンデンサ等の小物ワークを搬送供給するに際して、ワーク自体に方向性を有する場合が多いことから、例えばワークの表裏や縦横を一定の向きに整列しながら次の製造ラインに搬送供給するようにしている。そのために、異方向を向いたワークは、本来の供給用搬送路から隣接する別の回収用搬送路に移動させるようにしていて、夫々のワークを同時に搬送可能とする二つの搬送路を備えた所謂多列搬送を可能としたパーツフィーダが提案されている(例えば、特許文献2参照)。   However, when transporting and supplying small workpieces such as fine chip resistors and chip capacitors, there are many cases where the workpiece itself has directionality. For example, the next production line is arranged with the front and back and vertical and horizontal sides of the workpiece aligned in a certain direction. It is designed to be transported and supplied. For this purpose, the workpieces facing in different directions are moved from the original supply conveyance path to another adjacent collection conveyance path, and are provided with two conveyance paths that can convey each workpiece simultaneously. A parts feeder capable of so-called multi-row conveyance has been proposed (see, for example, Patent Document 2).

そこで、図10および図11は多列搬送のうち基本的な双方向搬送機能を備えた圧電式のパーツフィーダを示したもので、以下図面に基づき構成および作用につき説明する。
まず、図11に基づき説明すると、パーツフィーダ1は図示しない据付面に設置固定される一つのベースプレート2を備えているのに対し、多列搬送とするため後述する二つのトッププレート5,6を具備し、その間に前後に配した二対の圧電式振動励起手段を装備している。そのうちの一対は、前記ベースプレート2の前後(図示左右)に位置して各々の圧電素子3a,3aの下端が取付固定され、その各上端部に振動増幅用の板バネからなる一対の増幅バネ4a,4aが夫々連結されるとともに、更にこの増幅バネ4a,4aの上部を前記第1のトッププレート5に連結固定してなり、且ついずれも図示後方(左方向)に所定の傾斜角度倒れた連結構成としていて、この後方への傾斜に基づき該トッププレート5に矢印A方向の直進搬送可能な振動を付与している。
FIG. 10 and FIG. 11 show a piezoelectric parts feeder having a basic bidirectional transfer function in the multi-row transfer. The configuration and operation will be described below with reference to the drawings.
First, referring to FIG. 11, the parts feeder 1 is provided with a single base plate 2 that is installed and fixed on an installation surface (not shown). On the other hand, two top plates 5 and 6 to be described later are used for multi-row conveyance. It is equipped with two pairs of piezoelectric vibration excitation means arranged in the front and rear in between. A pair of them is located at the front and rear (left and right in the drawing) of the base plate 2 and the lower ends of the piezoelectric elements 3a, 3a are attached and fixed. , 4a are connected to each other, and the upper portions of the amplification springs 4a, 4a are connected and fixed to the first top plate 5, and both of them are tilted to the rear (left direction) by a predetermined inclination angle. The top plate 5 is vibrated in the direction of arrow A based on the backward inclination.

これに対し、もう一対のものも前記ベースプレート2と第2のトッププレート6との間に、上記と同一仕様の圧電素子3b,3bと増幅バネ4b,4bが連結固定され、ただ傾斜角度が上記とは等角度逆方向である図示前方(右方向)に傾斜している。なお、上記傾斜角度は、いずれもベースプレート2の各圧電素子3a,3b下端の取付基部2a,2aにおいて、予め所定の傾斜角度の傾斜面が形成されていて、この傾斜面に取付固定することで所定角度傾斜した位置決めがなされる。また、各圧電素子3a,3bの具体構成は省略するが、金属シム板7の両面に圧電セラミック板8aおよび8bを夫々電気的に導通状態に接合するとともに、これら圧電セラミック板8a,8bを分極処理して極性を持たせた構成としている。   On the other hand, the piezoelectric elements 3b and 3b and the amplification springs 4b and 4b having the same specifications as described above are connected and fixed between the base plate 2 and the second top plate 6 in the other pair. Is inclined forward (right direction) in the figure, which is the opposite direction of the same angle. Note that the inclination angle is such that an inclined surface having a predetermined inclination angle is formed in advance in the attachment base portions 2a and 2a at the lower ends of the piezoelectric elements 3a and 3b of the base plate 2, and is fixed to the inclined surface. Positioning at a predetermined angle is performed. Although the specific configuration of each piezoelectric element 3a, 3b is omitted, the piezoelectric ceramic plates 8a and 8b are electrically connected to both surfaces of the metal shim plate 7, respectively, and the piezoelectric ceramic plates 8a, 8b are polarized. It is configured to have polarity by processing.

しかるに、上記構成の第1,第2のトッププレート5,6上には、実施に際し図10に示すワーク搬送用の第1,第2のシュート9,10が搭載される。また、図11中に概略的に結線図を示すように、一対の圧電素子3a,3aの各圧電セラミック板11aはリード線12を介して一方の電源端子14に接続され、他方、共通の電源端子15にはリード線13を介して各圧電素子3a,3bの金属シム板7側と接続される。なお、もう一対の圧電素子3b,3bの各圧電セラミック板8bに対しても、図示しないが上記同様に結線され、以って夫々の圧電素子3a,3bに交流電圧を印加可能としている。   However, on the first and second top plates 5 and 6 having the above-described configuration, the work conveying first and second chutes 9 and 10 shown in FIG. In addition, as schematically shown in FIG. 11, the piezoelectric ceramic plates 11a of the pair of piezoelectric elements 3a, 3a are connected to one power supply terminal 14 via a lead wire 12, while the other common power supply The terminal 15 is connected to the side of the metal shim plate 7 of each piezoelectric element 3a, 3b through a lead wire 13. Although not shown, the piezoelectric ceramic plates 8b of the other pair of piezoelectric elements 3b and 3b are connected in the same manner as described above, so that an AC voltage can be applied to each of the piezoelectric elements 3a and 3b.

しかして、今図示しない制御用のコントローラを介して交流電圧が印加されると、各圧電素子3a,3bが励起されてたわみ振動し、増幅バネ4a,4bとで構成される振動系の共振周波数で強い振動を起こし、前記第1,第2のトッププレート5,6を介して当該シュート9,10上を、夫々図示しないワークが矢印A,B方向に搬送可能としている。このように、同時に互いに逆方向の所謂双方向へのワーク搬送を可能とするものであり、実施に際しては図示および詳細な説明は省略するが、上記供給用の第1のシュート9側には位置センサやワーク選別手段等が設けられ、そして選別除外された例えば異方向のワークを、回収用の第2のシュート10に移動させる手段等を備えている。   Thus, when an AC voltage is applied through a control controller (not shown), the piezoelectric elements 3a and 3b are excited to bend and vibrate, and the resonance frequency of the vibration system constituted by the amplification springs 4a and 4b. The workpieces (not shown) can be conveyed in the directions of arrows A and B through the first and second top plates 5 and 6 on the chutes 9 and 10, respectively. In this way, so-called bidirectional transfer of workpieces in opposite directions can be performed at the same time, and illustration and detailed description are omitted for implementation, but the first chute 9 for supply is positioned on the side of the first chute 9 for supply. A sensor, a work sorting means, and the like are provided, and a means for moving, for example, a work in a different direction, which has been excluded from sorting, to the second chute 10 for collection is provided.

上記構成によれば、ワークの多列搬送である双方向搬送機能を備え、方向性を有する小物部品たるワークの搬送に際して、選別された正方向のワークのみ供給用の第1のシュート9を介して矢印A方向に直進搬送して、先の製造ライン等への供給を可能とし、一方、異方向のワークは回収用の第2のシュート10に移動回収されて逆方向たる矢印B方向に搬送された後、再び第1のシュート9上に戻す手段を経て供給用のワークとして搬送されるようにしている。   According to the above-described configuration, a bi-directional conveyance function that is multi-row conveyance of workpieces is provided, and when a workpiece that is a small-sized component having directionality is conveyed, only the selected positive-direction workpiece is supplied via the first chute 9 for supply. Can be fed straight in the direction of arrow A and supplied to the previous production line, etc., while the workpiece in the opposite direction is moved and collected by the second chute 10 for collection and conveyed in the direction of arrow B in the reverse direction. Then, it is conveyed as a work for supply through means for returning it to the first chute 9 again.

上記構成のパーツフィーダ1によれば、多列搬送可能とするために言わば単機能のパーツフィーダを2台分組み合せた構成とし、そして二対(計4個)の圧電素子3a,3a,3b,3b全てに交流電圧を印加して通電駆動する構成にある。
しかるに、この駆動源であるうちの圧電素子3a若しくは3bに異常が発生した場合には、その都度当該圧電素子を新規取り替えなければならず、パーツフィーダ1も修復完了まで休止状態となり、実際にはこれに関連する製造ライン等も停止し、その生産能率の低下は免れない。しかも、この二対の圧電素子3a,3bは極力同一条件のもとで駆動させているが、各々の質量や変位量の複数の条件を一致させた上で同じ周波数に合わせ駆動せねばならず、その調整は難しく上記修復作業は容易ではない。また、計4個の圧電素子3a,3a,3b,3bは、いずれも当初から同じ長期間使用され例えば圧電セラミック板の耐久性(寿命)としても全てが同様の条件下にあり、上記のような取替え頻度も多くなる傾向にあり、実用に際して多列搬送可能なパーツフィーダ1として、取扱い上煩雑なメンテナンスを伴なうなど種々の問題を抱えている。
According to the parts feeder 1 having the above-described configuration, in order to enable multi-row conveyance, a single-function part feeder is combined for two units, and two pairs (four in total) of piezoelectric elements 3a, 3a, 3b, The configuration is such that the AC voltage is applied to all 3b to drive the current.
However, when an abnormality occurs in the piezoelectric element 3a or 3b, which is the driving source, the piezoelectric element must be replaced each time, and the parts feeder 1 is also in a suspended state until the repair is completed. The production line related to this will also be stopped, and the decline in production efficiency is inevitable. Moreover, the two pairs of piezoelectric elements 3a and 3b are driven under the same conditions as much as possible. However, they must be driven in accordance with the same frequency after matching a plurality of conditions of mass and displacement. The adjustment is difficult and the repair work is not easy. In addition, the total of four piezoelectric elements 3a, 3a, 3b, 3b are all used for the same long period from the beginning, and for example, the durability (life) of the piezoelectric ceramic plate is all under the same conditions as described above. Therefore, the parts feeder 1 that can be transported in multiple rows has various problems such as complicated maintenance in handling.

本発明は上記問題点を解決するために、多列搬送可能とするうちの一方の搬送機能の駆動源たる圧電素子のみを駆動することで、他方の搬送機能も有効に機能するようにして効率よく駆動でき、且つ各圧電素子の駆動条件の調整も簡易にできるなど、実用上の取扱いも容易なパーツフィーダとその駆動方法を提供することを目的とする。   In order to solve the above-mentioned problems, the present invention is efficient by driving only the piezoelectric element that is the drive source of one of the transport functions that can be transported in multiple rows, so that the other transport function also functions effectively. An object of the present invention is to provide a parts feeder that can be driven well and that can easily adjust the driving conditions of each piezoelectric element and that can be easily handled in practice, and a driving method thereof.

上記目的を達成するために、本発明のパーツフィーダは、多列搬送可能な複数のトッププレートとベースプレート間に、圧電素子および増幅バネを介して上下に連結してなる一対の振動励起部材を複数対設け、これら振動励起部材の下端を固定支持した前記ベースプレートを弾性部材を介して据付面に設置したことを主たる特徴とするものである。   In order to achieve the above object, the parts feeder according to the present invention includes a plurality of a pair of vibration excitation members that are vertically connected via a piezoelectric element and an amplification spring between a plurality of top plates and a base plate that can be conveyed in multiple rows. The main feature is that the base plate, which is provided in pairs and fixedly supports the lower ends of these vibration excitation members, is installed on the installation surface via an elastic member.

斯かる構成によれば、弾性部材を介して設置されたベースプレートを共通にして複数対の振動励起部材を配設したので、そのうちの少なくとも一対の振動励起部材を付勢することで他の振動励起部材を経て当該トッププレートに振動を付与することができ、所謂少数の駆動源にて同速度による多列搬送を可能ならしめ、複数対の圧電素子を使い分けできて効率よく長期使用できる。これにより、故障等による圧電素子の取替え頻度の軽減や、同一周波数とするなどの駆動条件の調整作業も軽減できて、取扱い容易でコストの低減にも有効なパーツフィーダを提供できる。   According to such a configuration, since a plurality of pairs of vibration excitation members are arranged in common with the base plate installed via the elastic member, other vibration excitations can be obtained by energizing at least one of the vibration excitation members. Vibration can be applied to the top plate through the member, so that multiple rows can be conveyed at the same speed with a small number of drive sources, and a plurality of pairs of piezoelectric elements can be used properly and can be used efficiently for a long time. As a result, it is possible to reduce the frequency of replacing the piezoelectric element due to a failure or the like, and to reduce the adjustment work of the driving conditions such as the same frequency, and it is possible to provide a parts feeder that is easy to handle and effective in reducing costs.

(第1の実施の形態)
以下、本発明を双方向搬送機能を有するパーツフィーダに適用した第1実施例につき、図1〜図6を参照して説明する。
そのうち、図1は、パーツフィーダ21の全体構成を示す外観斜視図、図2はシュート部分を除去した状態の外観斜視図、図3は右側面図、図4はシュート部分の具体的構成を説明するための斜視図、図5は図4中のC部の拡大図、そして図6は概略的な電気的構成を示す結線図で、これら図面に基づき以下に説明する。
(First embodiment)
A first embodiment in which the present invention is applied to a parts feeder having a bidirectional transfer function will be described below with reference to FIGS.
1 is an external perspective view showing the entire configuration of the parts feeder 21, FIG. 2 is an external perspective view with the chute portion removed, FIG. 3 is a right side view, and FIG. 4 is a specific configuration of the chute portion. FIG. 5 is an enlarged view of a portion C in FIG. 4, and FIG. 6 is a connection diagram showing a schematic electrical configuration, which will be described below based on these drawings.

まず、図2,3を参照してパーツフィーダ21の概略構成につき述べるに際し、本実施例では後述するように多列搬送するために二対の振動励起手段を備えているので、まずそのうちの一方の直進搬送を可能とする振動励起手段の構成につき説明する。
すなわち、ワークを搬送可能とする振動励起手段は、第1のトッププレート23とベースプレート22との間に、圧電素子24aと増幅バネ25aとを上下方向に鉛直に連結して前後に配してなる一対の第1の振動励起部材26を設けた構成からなる。具体的には、増幅バネ25aの各下端と圧電素子24aの各上端との連結部間に、前後方向でもある水平方向に所定の間隔を保つスペーサ27を介在して座板28およびボルト・ナット部材29にて締結し連結している。そして、上端部のトッププレート23に対し各増幅バネ25aの上端を座板30およびボルト部材31にて締結固定し、下端部のベースプレート22に対しては各圧電素子24aの下端を座板32およびボルト部材33にて締結固定している。
First, in describing the schematic configuration of the parts feeder 21 with reference to FIGS. 2 and 3, in the present embodiment, as will be described later, two pairs of vibration excitation means are provided for carrying in multiple rows. The configuration of the vibration excitation means that enables the straight-forward conveyance of the above will be described.
That is, the vibration exciting means that can convey the work is arranged between the first top plate 23 and the base plate 22 by vertically connecting the piezoelectric element 24a and the amplification spring 25a vertically. The configuration includes a pair of first vibration excitation members 26. Specifically, the seat plate 28 and the bolts and nuts are interposed between the connecting portions of the lower ends of the amplification springs 25a and the upper ends of the piezoelectric elements 24a with a spacer 27 maintaining a predetermined distance in the horizontal direction, which is also the front-rear direction. The member 29 is fastened and connected. The upper end of each amplification spring 25a is fastened and fixed to the top plate 23 at the upper end by a seat plate 30 and a bolt member 31, and the lower end of each piezoelectric element 24a is fixed to the seat plate 32 and the base plate 22 at the lower end. The bolt member 33 is fastened and fixed.

従って、ベースプレート22上に一対の振動励起部材26を介して第1のトッププレート23が支持された構成となり、図3に開示するようにトッププレート23と増幅バネ25aの固定位置と、圧電素子24aのベースプレート22への固定位置とを結んだ線が鉛直線に対し後方(図示左方)に角度θ1傾斜した形態となる。この傾斜角度θ1は、前記スペーサ27による水平方向の間隔と、圧電素子24aが増幅バネ25aより前方に位置していることに基づき決定される。よって、鉛直方向に連結して設けられた一対の振動励起部材26は、角度θ1後方に傾斜した状態に構成され、駆動源たる一対の圧電素子24aが通電駆動されると、振動が励起され各増幅バネ25aを介して増幅された縦方向のたわみ振動がトッププレート23に付与され、これは図示しないワークを図2中に示す矢印A方向(前方)に直進搬送すべく機能する。   Accordingly, the first top plate 23 is supported on the base plate 22 via the pair of vibration excitation members 26, and as shown in FIG. 3, the fixing position of the top plate 23 and the amplification spring 25a, and the piezoelectric element 24a. The line connecting the fixed position to the base plate 22 is inclined to the rear (left side in the figure) by an angle θ1 with respect to the vertical line. The inclination angle θ1 is determined based on the horizontal interval by the spacer 27 and the fact that the piezoelectric element 24a is positioned in front of the amplification spring 25a. Accordingly, the pair of vibration excitation members 26 connected in the vertical direction is configured to be inclined rearward by the angle θ1, and when the pair of piezoelectric elements 24a serving as the drive source is driven to be energized, vibration is excited and each A longitudinal flexural vibration amplified through the amplifying spring 25a is applied to the top plate 23, which functions to convey a workpiece (not shown) straight in the direction of arrow A (forward) shown in FIG.

なお、上記圧電素子24aは、具体構成は省略するが従来周知のように金属シム板34aを挟んで圧電セラミック板35aが接合され、更に分極処理等が施された構成にあって、これを前後に配置して一対の圧電素子24aとして前記振動励起部材26を増幅バネ25aとともに構成している。また、前記ベースプレート22は、形状的に複雑化するのを避けるべく二つの部材で構成しており、圧電素子24aの下端を直接連結固定した上部ベースプレート22aと、詳細は後述する下部ベースプレート22bとの連結固定した構成からなるもので、勿論一体構成としても機能的に何ら支障を来たすものではない。   The piezoelectric element 24a has a configuration in which a specific configuration is omitted, but a piezoelectric ceramic plate 35a is joined with a metal shim plate 34a sandwiched between them and polarization treatment or the like is performed as is well known. The vibration excitation member 26 is configured together with an amplification spring 25a as a pair of piezoelectric elements 24a. The base plate 22 is composed of two members so as not to be complicated in shape, and includes an upper base plate 22a in which the lower end of the piezoelectric element 24a is directly connected and fixed, and a lower base plate 22b to be described in detail later. It is composed of a connected and fixed structure, and of course, there is no functional problem even if it is an integral structure.

これに対し、側方に隣接されたもう一方の振動励起手段につき述べると、これはワークを上記とは逆方向の図2中の矢印B方向(後方)に直進搬送すべく機能する。すなわち、第2のトッププレート36と前記ベースプレート22との間に、圧電素子24bと増幅バネ25bとを上下方向に鉛直に連結してなる一対の第2の振動励起部材37を設けた構成からなり、上記第1の振動励起部材26に対し、図3に示す傾斜角度θ2が上記した傾斜角度θ1に対し、ほぼ等角度逆方向(前方)に傾斜している点を除き実質的に同じ構成にある。   On the other hand, when the other vibration exciting means adjacent to the side is described, it functions to convey the workpiece straightly in the direction of arrow B (rear) in FIG. That is, a pair of second vibration excitation members 37 formed by vertically connecting a piezoelectric element 24b and an amplification spring 25b vertically between the second top plate 36 and the base plate 22 are provided. The first vibration excitation member 26 has substantially the same configuration except that the inclination angle θ2 shown in FIG. 3 is inclined substantially in the opposite direction (forward) to the inclination angle θ1. is there.

すなわち、増幅バネ25bの各下端と圧電素子24bの各上端との連結部間には、前記スペーサ27を介在して座板28およびボルト・ナット部材29にて締結し連結している。この場合、前記した傾斜角度θ2が前方に傾斜するように、増幅バネ25bの後方位置に圧電素子24bが配置されている。そして、各増幅バネ24bの上端を第2のトッププレート36に座板30およびボルト部材31にて締結固定し、また各圧電素子24bの下端をベースプレート22に形成され垂直な取付面を有する取付基部38に、座板32およびボルト部材33にて締結固定している。   That is, between the connecting portions of the lower ends of the amplification springs 25b and the upper ends of the piezoelectric elements 24b, the spacers 27 are interposed and fastened by the seat plate 28 and the bolt / nut members 29. In this case, the piezoelectric element 24b is disposed at the rear position of the amplification spring 25b so that the inclination angle θ2 is inclined forward. And the upper end of each amplification spring 24b is fastened and fixed to the second top plate 36 by the seat plate 30 and the bolt member 31, and the lower end of each piezoelectric element 24b is formed on the base plate 22 and has a vertical mounting surface. 38 is fastened and fixed by a seat plate 32 and a bolt member 33.

斯くして、ベースプレート22上に一対の第2の振動励起部材37を介して第2のトッププレート36が支持された構成となすとともに、図3に開示したように鉛直線に対し前方(図示右方)に角度θ2傾斜した形態にあるので、駆動源たる一対の圧電素子24bが通電駆動されると、振動が励起され各増幅バネ25bを介して増幅された縦方向のたわみ振動が第2のトッププレート36に付与され、前記したようにワークを矢印B方向(後方)に直進搬送すべく機能する。   Thus, the second top plate 36 is supported on the base plate 22 via the pair of second vibration excitation members 37, and as shown in FIG. Therefore, when the pair of piezoelectric elements 24b as drive sources are energized and driven, the vibration is excited and the longitudinal flexural vibrations amplified through the respective amplification springs 25b are the second. It is given to the top plate 36 and functions to convey the workpiece straight in the direction of arrow B (backward) as described above.

そして、上記第1,第2のトッププレート23,36と、これに夫々対応した二対の振動励起部材26,37に対し、共通とするベースプレート22を構成する上部ベースプレート22aと下部ベースプレート22bとをボルト部材39にて複数箇所を締結し一体的に連結固定する。斯かる構成体を以って、ワークを矢印AおよびB方向の双方向に搬送可能なユニット42として構成される。   An upper base plate 22a and a lower base plate 22b that constitute a common base plate 22 for the first and second top plates 23 and 36 and the two pairs of vibration excitation members 26 and 37 corresponding to the first and second top plates 23 and 36, respectively. A plurality of locations are fastened by bolt members 39 to be integrally connected and fixed. With such a structure, it is configured as a unit 42 capable of transporting a workpiece in both directions of arrows A and B.

次いで、上記搬送ユニット42をボトムベースプレート40に連結し、該ボトムベースプレート40を据付面に設置する。具体的には、ベースプレート22の下部ベースプレート22bは、弾性部材としてのバネ部材41を介してボトムベースプレート40と連結されている。しかるに、上記弾性部材たるバネ部材41は、本実施例では矩形の板バネ状にあって、上記下部ベースプレート22bとボトムベースプレート40の前後端において、図3に示すように上下方向に僅かの隙間S1を存して、座板43およびボルト部材44により夫々連結している。   Next, the transport unit 42 is connected to the bottom base plate 40, and the bottom base plate 40 is installed on the installation surface. Specifically, the lower base plate 22b of the base plate 22 is connected to the bottom base plate 40 via a spring member 41 as an elastic member. However, the spring member 41, which is the elastic member, is in the form of a rectangular leaf spring in this embodiment, and has a slight gap S1 in the vertical direction at the front and rear ends of the lower base plate 22b and the bottom base plate 40 as shown in FIG. Are connected by a seat plate 43 and a bolt member 44, respectively.

また、このバネ部材41に対向する下部ベースプレート22bの前後端面には切欠部49が形成され、図3中に示すようにバネ部材41との間に前後方向の隙間S2を形成している。この隙間S2は、上下方向の前記隙間S1と前後端で連続する如き構成にあって、特には該下部ベースプレート22bがバネ部材41と確実に離間し、その振動機能を損なわないようにしている。
この結果、据付面に設置固定されるボトムベースプレート40上に、トッププレート23,36、振動励起部材26,37、およびベースプレート22等からなる多列搬送可能なユニット42がバネ部材41を介して弾性的に支持された構成にある。
Further, a notch 49 is formed in the front and rear end faces of the lower base plate 22b facing the spring member 41, and a front-rear direction gap S2 is formed between the spring member 41 as shown in FIG. The gap S2 is configured to be continuous with the gap S1 in the vertical direction at the front and rear ends. In particular, the lower base plate 22b is reliably separated from the spring member 41 so that the vibration function is not impaired.
As a result, the multi-row transportable unit 42 including the top plates 23 and 36, the vibration excitation members 26 and 37, the base plate 22 and the like is elastically supported via the spring member 41 on the bottom base plate 40 that is installed and fixed on the installation surface. In a supported configuration.

しかるに、上記構成の搬送ユニット42に対し、実用に供するとて目的・用途に叶った双方向搬送に対応した第1のシュート45、第2のシュート46が装着される。具体的には、図1の全体構成の斜視図、図4の要部の拡大斜視図、図5に示す図4中のC部の拡大図を参照して以下に説明する。すなわち、本実施例では前記第1のトッププレート23の上部には、第1のシュート45がボルト部材47にて取付固定され、また第2のトッププレート36には第2のシュート46がボルト部材47にて取付固定されている。
従って、上記第1のシュート45は、図4,5中に示す例えばチップコンデンサの如き小物部品のワークWを、次製造ラインへ供給する矢印A方向に搬送可能とし、一方隣接する第2のシュート46は、ワークWを矢印B方向に搬送可能としており、その詳細は後の作用説明で述べる。
However, the first chute 45 and the second chute 46 corresponding to the two-way conveyance that has been practically used for practical purposes are mounted on the conveyance unit 42 having the above configuration. Specifically, a description will be given below with reference to a perspective view of the overall configuration of FIG. 1, an enlarged perspective view of the main part of FIG. 4, and an enlarged view of a portion C in FIG. 4 shown in FIG. That is, in the present embodiment, the first chute 45 is attached and fixed to the upper portion of the first top plate 23 by the bolt member 47, and the second chute 46 is bolted to the second top plate 36. It is fixedly attached at 47.
Accordingly, the first chute 45 can convey the work W, which is a small component such as a chip capacitor, shown in FIGS. 4 and 5 in the direction of arrow A to be supplied to the next production line, while the adjacent second chute is provided. No. 46 can convey the workpiece W in the direction of arrow B, and details thereof will be described later in the explanation of operation.

そして、図6に示す結線図につき説明すると、まず矢印A方向に搬送可能とする第1の振動励起部材26側の一対の圧電素子24aにあっては、その各圧電セラミック板35aと接続した実線で示すリード線48a,48bを、圧着端子55を介して1本のリード線48とし、切換スイッチ50を経て制御用のコントローラ51の一方の電源端子52に接続される。一方、矢印B方向に搬送可能とする第2の振動励起部材37側の一対の圧電素子24bにあっては、その各圧電セラミック板35bと接続した破線で示すリード線53a,53bを、圧着端子55を介して1本のリード線53として、前記切換スイッチ50を経てコントローラ51の同じ一方の電源端子52に接続可能としている。   The connection diagram shown in FIG. 6 will be described. First, in the pair of piezoelectric elements 24a on the first vibration excitation member 26 side that can be conveyed in the direction of arrow A, solid lines connected to the respective piezoelectric ceramic plates 35a. Are connected to one power supply terminal 52 of the controller 51 for control via the changeover switch 50. The lead wires 48a and 48b shown in FIG. On the other hand, in the pair of piezoelectric elements 24b on the second vibration excitation member 37 side that can be conveyed in the direction of arrow B, the lead wires 53a and 53b indicated by broken lines connected to the respective piezoelectric ceramic plates 35b are connected to crimp terminals. One lead wire 53 can be connected to the same one power supply terminal 52 of the controller 51 through the changeover switch 50 through 55.

これに対し、他方の電源端子57には金属シム板34a,34bに導通した共通のリード線58が接続されている。
従って、夫々一対の圧電素子24a,24bから導出されたリード線48,53は、切換スイッチ50の可動接片cによる固定接点a,bへの切換動作に応じて一方の電源端子52に電気的に接続され、以ってAC電源54に選択的に接続され、夫々一対の圧電素子24a又は24bに交流電圧を印加可能としている。
On the other hand, a common lead wire 58 connected to the metal shim plates 34a and 34b is connected to the other power supply terminal 57.
Accordingly, the lead wires 48 and 53 led out from the pair of piezoelectric elements 24a and 24b are electrically connected to one power supply terminal 52 in accordance with the switching operation to the fixed contacts a and b by the movable contact piece c of the changeover switch 50. Therefore, it is selectively connected to the AC power source 54 so that an AC voltage can be applied to the pair of piezoelectric elements 24a or 24b.

次に、上記構成のパーツフィーダ21の作用につき説明する。
まず、図6の結線図において切換スイッチ50を操作して、可動接片cを固定接点a側に接続した状態とする。これにより、一対の第1の振動励起部材26側のみ付勢され、所謂一対の圧電素子24aのみが通電駆動され、この交流電圧が印加されることで励起された所定周波数の振動を発生する。従って、この場合は一対の圧電素子24aのみが、強制的に付勢され振動を発する駆動源となる。しかるに、この圧電素子24aを有する一対の第1の振動励起部材26は、具体的には金属シム板34aを介して共通のベースプレート22に連結支持され、且つ弾性部材たるバネ部材41を介してボトムベースプレート40に連結されているので、圧電素子24aの励起に基づく振動はベースプレート22全体に伝播され振動状態に保持される。
Next, the operation of the parts feeder 21 having the above configuration will be described.
First, in the connection diagram of FIG. 6, the changeover switch 50 is operated so that the movable contact piece c is connected to the fixed contact a side. As a result, only the pair of first vibration excitation members 26 are energized, only the so-called pair of piezoelectric elements 24a are energized and driven, and vibrations of a predetermined frequency excited by applying this AC voltage are generated. Accordingly, in this case, only the pair of piezoelectric elements 24a is a driving source forcibly energized to generate vibration. However, the pair of first vibration excitation members 26 having the piezoelectric elements 24a are specifically connected and supported to the common base plate 22 via the metal shim plate 34a, and the bottoms via the spring member 41 which is an elastic member. Since it is connected to the base plate 40, the vibration based on the excitation of the piezoelectric element 24a is propagated to the entire base plate 22 and held in the vibration state.

しかるに、他方の第2の振動励起部材37を構成する圧電素子24bは非通電状態にあるが、上記第1の振動励起部材26と共通のベースプレート22に固定支持されているため、一体的に共振し同様の振動状態にある。この結果、バネ部材41を介してベースプレート22に支持された多列搬送ユニット42は固有の振動数からなる一つの振動体として機能し、その振動は具体的には各増幅バネ25a,25bを介して各トッププレート23,36に増幅伝達される。ただし、第2の振動励起部材37は第1の振動励起部材26とは逆方向に傾斜(傾斜角度θ2)しているので、ワークを矢印A方向とは逆の矢印B方向に直進搬送し、以って双方向搬送を可能としている。   However, the piezoelectric element 24b constituting the other second vibration excitation member 37 is in a non-energized state, but is fixedly supported by the base plate 22 common to the first vibration excitation member 26. However, it is in the same vibration state. As a result, the multi-row transport unit 42 supported by the base plate 22 via the spring member 41 functions as one vibration body having a specific frequency, and the vibration is specifically transmitted via the respective amplification springs 25a and 25b. Are amplified and transmitted to the top plates 23 and 36. However, since the second vibration excitation member 37 is inclined in the opposite direction to the first vibration excitation member 26 (inclination angle θ2), the workpiece is conveyed straightly in the direction of arrow B opposite to the direction of arrow A, Thus, bidirectional transport is possible.

ここで、図4,5を参照してワークWの双方向搬送する一例につき簡略的に説明すると、第1のトッププレート23に装着された第1のシュート45には、ワークWを供給用として搬送するための断面V字状の直線トラック45aを形成していて、ワークWはその断面V字状の面と接して矢印A方向に移送される。しかるに、ワークWは例えば方向性を有するチップコンデンサの如き矩形の形態をなす場合、横長の整列状態を正規の移送形態として次製造ラインに搬送する一方、倒立状態など正規でないワークWは回収する必要がある。   Here, referring to FIGS. 4 and 5, an example of bidirectional conveyance of the workpiece W will be briefly described. The workpiece W is supplied to the first chute 45 attached to the first top plate 23. A straight track 45a having a V-shaped cross section for conveyance is formed, and the workpiece W is transferred in the direction of arrow A in contact with the surface having the V-shaped cross section. However, when the workpiece W has a rectangular shape such as a directional chip capacitor, for example, the horizontally aligned state is conveyed to the next production line as a regular transfer mode, while the non-regular workpiece W such as an inverted state needs to be collected. There is.

そこで、このようなワークWの移送状態を選別する手段として、例えば矩形板状の高さ規制部材56をトラック45a上に設けていて、倒立状態とか2段積みのように高いワークWが移送されてきた場合、該高さ規制部材56に当接させて下方に落下させる構成としている。その落下面は、第2のシュート46の平坦な溝状のトラック46aにあって、該トラック46aは矢印B方向に行くほど上昇する傾斜面となしている。従って、異方向などの選別されたワークWは第2のシュート46側の低い面のトラック46aに落下した後、矢印B方向に移送されて高い面に至り、該トラック46aの終端部で方向変換され、元の第1のシュート45の上流側に再度供給される。   Therefore, as a means for selecting the transfer state of the workpiece W, for example, a rectangular plate-shaped height regulating member 56 is provided on the track 45a, and the high workpiece W is transferred in an inverted state or two-stage stacking. In this case, the height restricting member 56 is brought into contact with the height restricting member 56 and dropped downward. The falling surface is in a flat groove-like track 46a of the second chute 46, and the track 46a is an inclined surface that rises in the direction of arrow B. Accordingly, the selected work W in the different direction or the like falls on the lower surface track 46a on the second chute 46 side, and then is transferred in the direction of arrow B to reach the higher surface, and the direction is changed at the end of the track 46a. And supplied again to the upstream side of the original first chute 45.

斯くして、正規の移送形態のワークWは第1のシュート45から次製造ラインへ供給すべく搬送され、一方異方向などの形態のワークWは高さ規制部材56により選別されて第2のシュート46側に移動され、所謂回収されて再度第1のシュート45側に補充供給され、このような動作が繰り返し行なわれ、第1のシュート45における正規のワークWをより多く次製造ラインに搬送共給可能としている。
なお、上記したワークWの選別手段たる高さ規制部材56は、一例としてその機能が概略理解できる程度に示したに過ぎず、実際上ではワークWの位置センサや当該ワークWを除外(回収移動)するためのエアー機構や光センサ等の検知手段等を備えて一層確実に選別回収できる構成が採用されている。
Thus, the workpiece W in the normal transfer form is transported from the first chute 45 to be supplied to the next production line, while the workpiece W in a different direction or the like is sorted by the height restricting member 56 to be second. It is moved to the chute 46 side, so-called recovered and replenished and supplied again to the first chute 45 side. Such an operation is repeated, and more regular workpieces W in the first chute 45 are conveyed to the next production line. It can be shared.
Note that the height regulating member 56 serving as the sorting means for the workpiece W described above is merely shown as an example so that the function can be roughly understood. In practice, the position sensor of the workpiece W and the workpiece W are excluded (recovery movement). In other words, a configuration is adopted in which an air mechanism and a detecting means such as an optical sensor are provided for more reliable sorting and collection.

このように、双方向搬送が可能なパーツフィーダ21によれば、駆動源として一対単位で圧電素子24a又は24bを通電駆動する構成にあるため、今駆動源としていた圧電素子24aに異常が発生した場合には、切換スイッチ50を切換操作して可動接片cを固定接点b側に閉成するよう切り換える。この結果、代わって圧電素子24bが駆動源として励起され、上記同様の振動経緯にて双方向搬送を続いて実行できる。   As described above, according to the parts feeder 21 capable of bidirectional conveyance, since the piezoelectric element 24a or 24b is energized and driven as a pair of drive units, an abnormality has occurred in the piezoelectric element 24a that is now the drive source. In this case, the changeover switch 50 is changed over so that the movable contact piece c is closed to the fixed contact b side. As a result, the piezoelectric element 24b is excited instead as a drive source, and bidirectional conveyance can be continuously executed with the same vibration process as described above.

なお、上記異常時の検知手段としては、例えば圧電素子24aに異常が発生したとすると、リード線48と共通のリード線58間に抵抗が発生し、このとき通常の駆動電流の数倍の電流が流れる。従って、その異常電流を検知し異常信号を発して報知するようにすればよい。従って、その異常信号を解除した後、駆動源たる他方の圧電素子の通電駆動に切り換えることは容易にできる。この場合、本実施例では上記した切換スイッチ50の切換操作により行なわれるが、固定接点a,bの中間にOFF用(停止用)の固定接点dを設けることにより、随時駆動源をOFFすることができ使い勝手は向上する。   As a means for detecting the abnormality, for example, if an abnormality occurs in the piezoelectric element 24a, a resistance is generated between the lead wire 48 and the common lead wire 58. At this time, a current several times the normal drive current is generated. Flows. Therefore, it is only necessary to detect the abnormal current and issue an abnormal signal for notification. Therefore, after canceling the abnormal signal, it is possible to easily switch to energization driving of the other piezoelectric element as a driving source. In this case, in this embodiment, the operation is performed by the changeover operation of the changeover switch 50 described above, but the drive source is turned off at any time by providing an OFF (stop) fixed contact d between the fixed contacts a and b. And usability is improved.

このように、本実施例によれば次の効果を有する。
双方向搬送などの多列搬送を可能とするパーツフィーダ21は、通常の2台分の機能を有する多列搬送ユニット42として共通のベースプレート22に一体的に設けられた構成にあって、この搬送ユニット42をバネ部材41を介してボトムベースプレート40に連結して弾性的に支持するとともに、該ボトムベースプレート40を据付面に設置する構成とした。従って、搬送ユニット42は単一の固有の振動体として保持される。この結果、やはり駆動源として2台分の圧電素子24a,および24bを夫々一対備えているが、実施に際してはそのうちの一方の駆動源たる一対の圧電素子24a、又は一対の圧電素子24bの何れかを選択駆動させればよい。所謂1台分の搬送機能を発揮する一つの駆動源で2台分に相当する双方向搬送などの多列搬送ができる。
Thus, according to this embodiment, the following effects are obtained.
The parts feeder 21 that enables multi-row conveyance such as bidirectional conveyance has a configuration in which it is integrally provided on a common base plate 22 as a multi-row conveyance unit 42 having the function of two ordinary units. The unit 42 is connected to the bottom base plate 40 via the spring member 41 and elastically supported, and the bottom base plate 40 is installed on the installation surface. Accordingly, the transport unit 42 is held as a single unique vibrator. As a result, a pair of piezoelectric elements 24a and 24b are also provided as driving sources, but either one of the pair of piezoelectric elements 24a or the pair of piezoelectric elements 24b is one of the driving sources. May be selectively driven. Multi-line conveyance such as bidirectional conveyance corresponding to two units can be performed by one drive source that exhibits a so-called conveyance function for one unit.

このため、従前の手段の如く2台分の駆動源たる本実施例で言えば二対の圧電素子24aおよび24bを同時に通電駆動するような構成に比し、何れか一方の一対の圧電素子を付勢するだけでよく、同じ駆動条件に調整する手間も軽減できるとともに、コントロールも単純化でき容易に制御できる。また、使用中の圧電素子が寿命などで異常を来たした場合は、従前ではその都度異常の圧電素子を取り替えるなどの面倒なメンテナンス作業を要したが、本実施例によれば他の圧電素子の使用に速やかに切り換えることができ、パーツフィーダ21として継続して実施できる。   Therefore, in this embodiment, which is a drive source for two units as in the conventional means, compared to a configuration in which two pairs of piezoelectric elements 24a and 24b are energized and driven at the same time, either one pair of piezoelectric elements is used. It only needs to be energized, and the labor for adjusting to the same driving conditions can be reduced, and the control can be simplified and easily controlled. In addition, when a piezoelectric element in use has become abnormal due to its life, etc., it has previously required troublesome maintenance work such as replacing the abnormal piezoelectric element each time. The parts feeder 21 can be continuously implemented.

しかも、圧電素子の異常時には通常の駆動電流の数倍流れる異常電流を検知することで容易に認知できるとともに、その監視体制も容易に設けることができる。しかも、本実施例の如き切換スイッチ50による簡単な切り換え操作だけで、休止していた他方の圧電素子を付勢することができ、即続いて搬送作業が実行できて製造ライン等を長時間休止することもなくい。   In addition, when the piezoelectric element is abnormal, it can be easily recognized by detecting an abnormal current that flows several times the normal driving current, and a monitoring system can be easily provided. Moreover, the other piezoelectric element that has been paused can be energized by a simple switching operation by the changeover switch 50 as in the present embodiment, and the carrying operation can be executed immediately, so that the production line is paused for a long time. No need to do.

斯くして、実施に当たり取扱い性も良好でワークの搬送作業も効率よくでき生産性の向上を図ることができる。また、二対の圧電素子24a,24bを一対単位で2回に使い分けできるので、面倒なメンテナンス作業を軽減できて長期使用できるとともに、安定した搬送性能を維持できてコスト低減にも大いに有利である。また、共通のベースプレート22に対し2台分以上の搬送ユニットを設けることも可能で、勿論この場合も該当する多列搬送機能よりも少数の駆動源で対応でき、上記同様の効果が期待できる。   Thus, in handling, the handling property is good, the work transfer operation is efficient, and the productivity can be improved. In addition, since the two pairs of piezoelectric elements 24a and 24b can be selectively used twice as a pair, it is possible to reduce troublesome maintenance work and use it for a long period of time, and it is possible to maintain stable conveyance performance, which is very advantageous for cost reduction. . Also, it is possible to provide two or more transport units for the common base plate 22, and of course, this case can be handled with a smaller number of drive sources than the corresponding multi-row transport function, and the same effect as described above can be expected.

なお、本実施例ではボトムベースプレート40を介して据付面に設置固定する構成としたが、これに限らず、例えばバネ部材41をL字状に曲成して、該バネ部材41の一端を直接据付面に設置固定する構成とすることも可能である。また、バネ部材41は前後端において連結する構成としたが周囲全体に配設してもよいし、且つそれに応じた種々の形状が考えられる。   In the present embodiment, it is configured to be installed and fixed to the installation surface via the bottom base plate 40, but the present invention is not limited to this. For example, the spring member 41 is bent in an L shape and one end of the spring member 41 is directly connected to the installation surface. It is also possible to adopt a configuration in which installation is fixed to the installation surface. Further, although the spring member 41 is connected at the front and rear ends, the spring member 41 may be disposed around the entire periphery, and various shapes are conceivable.

一方、圧電素子24a,24bの異常時には、図6に開示したようにスイッチ手段として切換スイッチ50により手動で切換操作するようにしたが、例えば異常電流検知手段を設けて上記切換スイッチ50に相当するスイッチ手段を連動させるなど、所望に応じた自動化による制御も容易に展開できる。また、スイッチ手段としては切換スイッチ50に代えて、例えばリード線38や53に対し直列に開閉するスイッチ手段を夫々設けた構成でもよいなど、種々変更し実施可能である。   On the other hand, when the piezoelectric elements 24a and 24b are abnormal, the switching means 50 is manually switched by the changeover switch 50 as disclosed in FIG. 6. For example, an abnormal current detection means is provided and corresponds to the changeover switch 50. Control by automation as desired, such as linking switch means, can be easily developed. Further, as the switch means, instead of the change-over switch 50, for example, a switch means that opens and closes in series with respect to the lead wires 38 and 53 may be provided, and various modifications can be made.

(第2の実施の形態)
次に、図7および図8は本発明の第2実施例を示す、夫々図2および図3相当図であって、上記第1実施例と実質的に同一部分には同一符号を付して説明を省略し、異なる部分につき説明する。
上記実施例では、弾性部材として板バネ状のバネ部材41を用いたのに対し、このものは弾性ゴム製によるゴム部材59を採用した点で異なるもので、その余の構成は実質的に上記実施例と同じである。
(Second Embodiment)
Next, FIGS. 7 and 8 show a second embodiment of the present invention, which corresponds to FIGS. 2 and 3, respectively, and substantially the same parts as those in the first embodiment are denoted by the same reference numerals. Description is omitted, and different parts will be described.
In the above embodiment, the plate spring-like spring member 41 is used as the elastic member. However, this is different in that a rubber member 59 made of elastic rubber is used, and the remaining configuration is substantially the same as described above. The same as the embodiment.

以下、具体的に説明すると本実施例ではベースプレート22を構成する上下部ベースプレート22a,22bのうち、下部ベースプレート22bにおいて上記実施例とは若干異なる形状としている。すなわち、下部ベースプレート22bは特に図7の斜視図から理解できるように矩形平板状をなし、その下面側の4隅部に前記ゴム部材59を配設できる表面積を確保した形状としている。しかるに、ゴム部材59は図8に破断して示すように、円柱状をなし上部にボルト部材60を配し、また下部に固定脚61を配してモールド成形により一体的に構成している。   Specifically, in this embodiment, of the upper and lower base plates 22a and 22b constituting the base plate 22, the lower base plate 22b has a slightly different shape from the above embodiment. That is, the lower base plate 22b has a rectangular flat plate shape as can be understood from the perspective view of FIG. 7, and has a shape that secures a surface area on which the rubber member 59 can be disposed at the four corners on the lower surface side. However, the rubber member 59 has a columnar shape as shown in a broken view in FIG. 8, and a bolt member 60 is disposed at the upper portion, and a fixed leg 61 is disposed at the lower portion, and is integrally formed by molding.

しかるに、ボルト部材60は下部ベースプレート22bを下方より貫通して、その突出端部をナット締めすることで固定され、ベースプレート22に連結される。一方、下部の固定脚61は剛性部材で形成され、その長孔状の取付孔61aを介して据付面にボルト締めするなどして固定し設置される。この場合、4個の固定脚61は外方に突出した位置にするなど自由に設定できるもので、下部ベースプレート22bに挿通したときに所望の方向位置に定めて締め付け固定すればよい。   However, the bolt member 60 passes through the lower base plate 22b from below and is fixed by tightening the protruding end with a nut, and is connected to the base plate 22. On the other hand, the lower fixing leg 61 is formed of a rigid member, and is fixed and installed, for example, by bolting to the installation surface via the elongated mounting hole 61a. In this case, the four fixed legs 61 can be freely set, for example, so as to protrude outward, and when they are inserted through the lower base plate 22b, they may be fixed in a desired direction.

上記構成によれば、弾性部材たるゴム部材59が上部の搬送ユニット42を弾性的に支持したことにより、該ユニット42が有する例えば一対の圧電素子24aが通電付勢され発生した振動に基づき一体的な搬送ユニット42全体を共振した振動状態のまま保持することができる。従って、非通電状態にある他の一対の圧電素子24bを有する第2の振動励起部材37にも振動が伝達され、これに連結支持された第2のトッププレート36側にも振動が伝達付与されて矢印B方向へのワークの搬送を可能とする。   According to the above configuration, the rubber member 59, which is an elastic member, elastically supports the upper transport unit 42, so that, for example, the pair of piezoelectric elements 24a included in the unit 42 is energized and energized to generate a unity. The entire transport unit 42 can be held in a resonating vibration state. Accordingly, the vibration is transmitted to the second vibration excitation member 37 having the other pair of piezoelectric elements 24b in a non-energized state, and the vibration is also transmitted to the second top plate 36 connected and supported by the second vibration excitation member 37. The workpiece can be conveyed in the direction of arrow B.

このように、ゴム部材59からなる弾性部材を用いても、搬送ユニット42を一つの固有振動体として保持することができ、上記第1実施例と同様の作用効果が期待できる。
なお、本実施例では固定脚61にて据付面に設置する構成としたが、これに限らず第1実施例の如きボトムベースプレート40を設けて、これの上面にゴム部材59を配し、下面側を据付面に設置する構成としてもよい。
As described above, even if an elastic member made of the rubber member 59 is used, the transport unit 42 can be held as one natural vibration body, and the same effect as the first embodiment can be expected.
In this embodiment, the fixed leg 61 is installed on the installation surface. However, the present invention is not limited to this, and the bottom base plate 40 as in the first embodiment is provided, the rubber member 59 is disposed on the upper surface thereof, and the lower surface is provided. It is good also as a structure which installs the side in an installation surface.

(第3の実施の形態)
そして、図9は本発明の第3実施例を示す図2相当図で、更にはこれに結線図を付記したもので、上記第1実施例と実質的に同一部分には同一符号を付して説明を省略し、異なる部分につき説明する。
上記実施例では、例えば第1の振動励起部材26は、これを構成する圧電素子24aおよび増幅バネ25aは、スペーサ27を介していずれも鉛直方向に連結固定されているのに対し、本実施例における振動励起部材26は、スペーサ27を使用しないで全体に角度θ1傾斜した状態に圧電素子24aおよび増幅バネ25aが連結した構成であること、および第2の振動励起部材37に代えて増幅バネ25bのみにより連結された振動伝達部材62を備えた構成において異なり、その余の構成は実質的に上記第1実施例と同じである。
(Third embodiment)
FIG. 9 is a view corresponding to FIG. 2 showing a third embodiment of the present invention, and further, a connection diagram is added thereto, and substantially the same parts as those in the first embodiment are denoted by the same reference numerals. The description will be omitted, and different parts will be described.
In the above embodiment, for example, in the first vibration excitation member 26, the piezoelectric element 24a and the amplification spring 25a constituting the first vibration excitation member 26 are both connected and fixed in the vertical direction via the spacer 27. The vibration excitation member 26 in FIG. 5 has a configuration in which the piezoelectric element 24a and the amplification spring 25a are coupled to each other without using the spacer 27, and the amplification spring 25b is replaced with the second vibration excitation member 37. However, the remaining configuration is substantially the same as that of the first embodiment.

まず、上記振動励起部材26側の構成につき説明すると、ベースプレート22を構成する上部ベースプレート22aには、所定角度θ1後方に傾斜した取付面を有する取付基台38が突設されていて、圧電素子24aを構成する金属シム板34aの下端をボルト部材33等で締結固定している。そして、この上端に直線的に連結された増幅バネ25aの各上端を、やはり傾斜面をなす第1のトッププレート23の前後端部に取付固定される。このように、トッププレート23とベースプレート22間を傾斜状態に連結してなる一対の振動励起部材26にあって、その一対の圧電素子24aにリード線48,58を介して交流電圧を印加することで、当該トッププレート23にはワークを矢印A方向に直進搬送可能な振動が付与される。   First, the configuration on the vibration excitation member 26 side will be described. The upper base plate 22a constituting the base plate 22 is provided with a mounting base 38 having a mounting surface inclined rearward by a predetermined angle θ1, and the piezoelectric element 24a. The lower end of the metal shim plate 34a is fixed by a bolt member 33 or the like. Then, the upper ends of the amplification springs 25a linearly connected to the upper ends are attached and fixed to the front and rear end portions of the first top plate 23 that also forms an inclined surface. Thus, in the pair of vibration excitation members 26 formed by connecting the top plate 23 and the base plate 22 in an inclined state, an alternating voltage is applied to the pair of piezoelectric elements 24a via the lead wires 48 and 58. Thus, vibration is applied to the top plate 23 so that the workpiece can be conveyed straight in the direction of arrow A.

これに対し、第2のトッププレート36とベースプレート22間を上記とは逆方向の傾斜状態に連結してなる一対の振動伝達部材62は、駆動源たる圧電素子を有しない増幅バネ25bからなるもので、更に具体的に述べれば圧電セラミック板を有しない金属シム板34bのみを利用して連結され、他方の振動励起部材26の固有振動数に合わせた構成としている。従って、この振動伝達部材62は自ら振動を励起するものでないが、他方の振動励起部材26の一対の圧電素子24aに交流電圧が印加されれば、バネ部材41にて支持された共通のベースプレート22等からなる搬送ユニット42全体が共振し、この結果、振動伝達部材62を経て第2のトッププレート36に矢印B方向に搬送する振動が付与される構成にある。   On the other hand, the pair of vibration transmitting members 62 formed by connecting the second top plate 36 and the base plate 22 in an inclined state opposite to the above is composed of an amplification spring 25b having no piezoelectric element as a driving source. More specifically, it is connected using only the metal shim plate 34b having no piezoelectric ceramic plate, and is configured to match the natural frequency of the other vibration excitation member 26. Therefore, the vibration transmitting member 62 does not excite vibration by itself, but if an AC voltage is applied to the pair of piezoelectric elements 24a of the other vibration exciting member 26, the common base plate 22 supported by the spring member 41 is used. As a result, the entire conveyance unit 42 is resonated, and as a result, the vibration to be conveyed in the direction of arrow B is applied to the second top plate 36 via the vibration transmission member 62.

斯かる構成によれば、一対の圧電素子24aを通電駆動するのみで多列搬送が可能であり、所謂1台分の少数の駆動源で双方向搬送等が可能となる。従って、駆動条件を調整する手間も軽減できるとともに、コントロールも単純化でき容易に制御でき、且つ簡易な構成にて配線処理も容易で取扱いも容易であるなど、そしてコスト低減にも有利なパーツフィーダ21を提供できる。   According to such a configuration, multi-row conveyance is possible only by energizing and driving the pair of piezoelectric elements 24a, and bidirectional conveyance or the like is possible with a small number of so-called single drive sources. Therefore, it is possible to reduce the effort to adjust the driving conditions, simplify the control, easily control, the wiring process is easy and easy to handle with a simple configuration, and the parts feeder is advantageous for cost reduction. 21 can be provided.

なお、本発明は弾性部材たるバネ部材やゴム部材は、ベースプレートとボトムベースプレート間の連結、或いはベースプレートと据付面との間に連結され、搬送ユニットを据付面に対し弾性支持することが可能であることから、該弾性部材は上記実施例に限定されることなく種々の形態に展開可能で、例えばコイルバネや屈曲した板バネなどのバネ部材とか、或いは平板状のゴム部材などを介在して設置する構成としてもよい。   In the present invention, the spring member or rubber member, which is an elastic member, is connected between the base plate and the bottom base plate or between the base plate and the installation surface, and can elastically support the transport unit with respect to the installation surface. Therefore, the elastic member can be developed in various forms without being limited to the above-described embodiments. For example, the elastic member is installed via a spring member such as a coil spring or a bent leaf spring, or a flat rubber member. It is good also as a structure.

その他、上記実施例における2列の多列搬送に限らず3列以上の多列搬送にも展開可能で、この場合にも例えば3台分の搬送機能を有するのに対し、それよりも少ない駆動源にて対処できることから、上記実施例と同様な効果が期待できるものであり、勿論、双方向搬送に限らず同じ方向に同時に複数の直進搬送を行なう場合にも、同一条件で駆動できて多列搬送を効率よく実施できるなど、実施に際して本発明の要旨を逸脱しない範囲内で種々変更して実施し得るものである。   In addition, the present invention can be developed not only for the two-row multi-row conveyance in the above-described embodiment but also for the multi-row conveyance of three or more rows. The same effect as in the above-described embodiment can be expected because it can be dealt with at the source. Of course, the present invention is not limited to bi-directional conveyance, and can be driven under the same conditions when performing a plurality of linear conveyances simultaneously in the same direction. Various modifications can be made without departing from the scope of the present invention, such as efficient row conveyance.

本発明の第1実施例を示すパーツフィーダの外観斜視図1 is an external perspective view of a parts feeder showing a first embodiment of the present invention. シュートを取外した状態の図1相当図Figure equivalent to Figure 1 with the chute removed 側面図Side view シュート部分を拡大して示す斜視図The perspective view which expands and shows a chute part 図4中の符号Cで示す要部の拡大図The enlarged view of the principal part shown by the code | symbol C in FIG. 概略的な電気的構成を示す結線図Connection diagram showing schematic electrical configuration 本発明の第2実施例を示す図2相当図FIG. 2 equivalent diagram showing a second embodiment of the present invention. 一部破断して示す図3相当図Fig. 3 equivalent view partially broken 本発明の第3実施例を示す図2相当図FIG. 2 equivalent view showing a third embodiment of the present invention. 従来例を示す図1相当図1 equivalent diagram showing a conventional example 図2相当図2 equivalent diagram

符号の説明Explanation of symbols

図面中、21はパーツフィーダ、22はベースプレート、23は第1のトッププレート、24a,24bは圧電素子、25a,25bは増幅バネ、26は第1の振動励起部材、36は第2のトッププレート,37は第2の振動励起部材、40はボトムベースプレート、41はバネ部材(弾性部材)、42は搬送ユニット、45は第1のシュート、46は第2のシュート、59はゴム部材(弾性部材)、61は固定脚、および62は振動伝達部材を示す。   In the drawings, 21 is a parts feeder, 22 is a base plate, 23 is a first top plate, 24a and 24b are piezoelectric elements, 25a and 25b are amplification springs, 26 is a first vibration excitation member, and 36 is a second top plate. , 37 is a second vibration excitation member, 40 is a bottom base plate, 41 is a spring member (elastic member), 42 is a transport unit, 45 is a first chute, 46 is a second chute, and 59 is a rubber member (elastic member). ), 61 is a fixed leg, and 62 is a vibration transmitting member.

Claims (3)

多列搬送可能な複数のトッププレートとベースプレート間に、圧電素子および増幅バネを介して上下に連結してなる一対の振動励起部材を複数対設け、これら振動励起部材の下端を固定支持した前記ベースプレートを弾性部材を介して据付面に設置したことを特徴とするパーツフィーダ。   The base plate in which a plurality of pairs of vibration excitation members, which are vertically connected via a piezoelectric element and an amplification spring, are provided between a plurality of top plates and base plates that can be conveyed in multiple rows, and the lower ends of these vibration excitation members are fixedly supported A parts feeder characterized in that is installed on the installation surface via an elastic member. 多列搬送可能な複数のトッププレートとベースプレート間に、圧電素子および増幅バネを介して上下に連結してなる一対の振動励起部材を複数対設け、これら振動励起部材の下端を固定支持した前記ベースプレートを弾性部材を介して据付面に設置したものにあって、前記圧電素子に対し一対単位で通電切換可能としたことを特徴とするパーツフィーダの駆動方法。   The base plate in which a plurality of pairs of vibration excitation members, which are vertically connected via a piezoelectric element and an amplification spring, are provided between a plurality of top plates and base plates that can be conveyed in multiple rows, and the lower ends of these vibration excitation members are fixedly supported A method of driving a parts feeder, characterized in that the energization switching of the piezoelectric element can be performed in pairs as a unit. 多列搬送可能な複数のトッププレートとベースプレート間に、圧電素子および増幅バネを介して上下に連結してなる少なくとも一対の振動励起部材と、前記圧電素子を有せず前記増幅バネを介して上下に連結してなる少なくとも一対の振動伝達部材とを設け、これら両部材の下端を固定支持した前記ベースプレートを弾性部材を介して据付面に設置したことを特徴とするパーツフィーダ。

At least a pair of vibration excitation members that are vertically connected via a piezoelectric element and an amplification spring between a plurality of top plates and base plates that can be conveyed in multiple rows, and the upper and lower sides via the amplification spring without the piezoelectric element. A parts feeder characterized in that at least a pair of vibration transmission members connected to each other is provided, and the base plate that fixes and supports the lower ends of both members is installed on an installation surface via an elastic member.

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR100979319B1 (en) 2007-05-01 2010-08-31 가부시기가이샤 다이신 Vibratory conveying apparatus
CN110498192A (en) * 2019-09-07 2019-11-26 深圳市晶展鑫电子设备有限公司 The continuous material of intelligent piezo or feed supplementing device

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR100979319B1 (en) 2007-05-01 2010-08-31 가부시기가이샤 다이신 Vibratory conveying apparatus
CN101298295B (en) * 2007-05-01 2011-12-14 株式会社大伸 Vibration type convey
CN110498192A (en) * 2019-09-07 2019-11-26 深圳市晶展鑫电子设备有限公司 The continuous material of intelligent piezo or feed supplementing device
CN110498192B (en) * 2019-09-07 2024-06-11 深圳市晶展鑫电子设备有限公司 Intelligent piezoelectric feeding or supplementing device

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