JP2007238102A - Manual driving type binding tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve and provide an inexpensive binding tool having a manually driving structure which is more inexpensive than a conventional electric binding tool having a built-in electric motor, and used even in a small factory for small lot production, individual shops, or developing countries. <P>SOLUTION: A manually driving type binding device A comprises a tool body H for performing a series of binding operations by feeding a binding band 1, winding the band around a work W to be bound, and tightening and binding the band, a manual power unit K for supplying the power necessary for performing a series of binding operations to the tool body H by the manual operation, and a transmission mechanism D for transmitting the power generated by the manual power unit K to a power inputting unit n of the tool body H; and further comprises an incomplete binding preventive means F which is functioned so that the next binding operation can be started only when the operational amount of the manual power unit K reaches the specified level for generating the power amount necessary for performing one cycle of the binding operation in the tool body H. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an artificially driven binding tool in which a binding tool having a structure that does not have a drive source is driven by human power.

  The bundling tool is to bind the bundling object with a dedicated bundling band (also called “bundling tie” or simply “tie”), and the bundling object includes a wire group, a pipe group, various long products, etc. There are various types, but representative ones include wire harnesses that are frequently used in vehicles such as automobiles, construction machines, and work machines. Conventionally, as a binding tool of this type, as disclosed in Patent Document 1 and Patent Document 2, a tool body, a grip handle attached below the tool body, and a pair equipped at the tip of the tool body. There is known a handy type having a flange member. Mail

  The bundling tools disclosed in these Patent Documents 1 and 2 are of an electric type in which a series of operations are driven by an electric motor. In addition to mechanical devices necessary for bundling, an electric motor for driving, Many electric-related parts and devices such as electric circuits, display lamps, various sensors, electric switches and the like are necessary, and the total bundling tool has been relatively expensive.

Therefore, it is difficult to be expensive for use in small-scale factories that produce small quantities, private shops, developing countries, and the like, and it has been difficult to mechanize the bundling work. However, since it takes too much labor to cover the bundling operation manually, and the work efficiency is not good, there is an increasing demand for an inexpensive bundling tool.
Japanese Patent Laid-Open No. 10-180646 JP-A-10-250707

  An object of the present invention is to have a built-in electric motor as a structure in which a convenient bundling tool that can be mechanically bundled using a bundling band is driven by human power instead of an electric motor built in the tool. Compared to conventional electric binding tools, it is possible to realize and provide a low-cost binding tool that can be used in small-scale factories, private shops, developing countries, etc. It is in the point to do.

  According to the first aspect of the present invention, in the artificially driven binding tool, the tool main body H for performing a series of binding operations for sending out the binding band 1 and winding the binding band 1 around the binding target W and tightening and binding them, and by manual operation. In order to supply the tool body H with the power necessary to perform the series of bundling operations, an artificial power unit K configured separately from the tool body H, and the power generated in the artificial power unit K A transmission mechanism D that transmits power to the power input unit n of the tool body H, and the amount of operation of the artificial power unit K generates the amount of power necessary to perform one cycle of the bundling operation in the tool body H. Only when the prescribed level is reached, the incomplete bundling prevention means F that functions so that the next bundling operation can be started is provided.

According to a second aspect of the present invention, in the artificially driven binding tool according to the first aspect, the artificial power unit K includes a human-operated pedal 4 that can be freely moved downward by stepping and moved up and returned by releasing the stepping. Composed of pedal devices,
The transmission mechanism D is configured to have a Bowden wire 5 that transmits the pushing and pulling power by the artificial operation pedal 4 to the power input unit n.
The power input unit n forcibly rotates the input shaft 34 in a predetermined direction by one of the push-pull movements by the Bowden wire 5, and the input shaft 34 is moved by the other push-pull movement. It has a power conversion mechanism E with a one-way clutch Cr that functions so as not to rotate,
The incomplete bundling prevention means F is configured such that the ratchet 43 in the one-way clutch Cr and the clutch pawl 42a that can mesh with the ratchet 43 are mutually moved along with the upward return movement after depressing to the limit of the artificial operation pedal 4. The one-way clutch Cr is set so as to be changed to a different combination.

According to a third aspect of the present invention, in the artificially driven binding tool according to the second aspect, the power conversion mechanism E, the rack gear 30 connected to the inner cable 5A of the Bowden wire 5, and the input shaft 34 are fitted. The one-way clutch Cr includes a ratchet 43 pivotally supported by the pinion gear 31 in an integrally rotated state, and the input shaft. A plurality of clutch claws 42a provided in an integrally rotating state on the 34th side,
The incomplete bundling prevention means F is set such that the rotational movement amount of the ratchet 43 due to the most depression of the artificial operation pedal 4 is slightly larger than the circumferential interval between the adjacent clutch claws 42a. It is characterized by being comprised.

  According to the present invention, since the bundling tool has a structure that requires a human drive as a driving source, relatively expensive electrical components and a set of devices such as an electric motor, a power circuit associated therewith, and a display lamp are not required at all in the tool body. The cost can be greatly reduced. However, although a drive mechanism as an artificial power unit is required, it can be a general one (oscillating pedal, operation handle, etc.), so it can be used in comparison with a dedicated electric facility such as a conventional electric binding tool. Since it can be covered with much cheaper ones, the total cost can be clearly reduced. As a result, a conventional bundling tool that can be bundled mechanically using a bundling band has a built-in electric motor as its drive source driven by human power instead of an electric motor built in the tool. It is possible to realize and provide an inexpensive binding tool that can be used in small-scale factories, private stores, developing countries, etc. .

  In addition, as will be described in detail in the section of the embodiment, by providing the incomplete bundling prevention means, the operation of the artificial power unit is stopped halfway, and the artificial power unit in a state once returned to the initial operation position from there. Even when the operation is performed again, if the artificial power unit is operated to the end of the operation range, one cycle of the binding operation is performed as expected, and the binding can be performed satisfactorily. Thereby, even if some inconvenience or failure occurs and the operation of the artificial power unit is interrupted and then re-operated, there is an advantage that the next bundling operation can be satisfactorily bound without being disabled.

  The incomplete bundling preventing means is a ratchet in a one-way clutch equipped in the power input unit, as in claim 2, wherein the structure is such that the depressing force of the artificial operation pedal is transmitted to the power input unit of the bundling tool via the Bowden wire. It is possible to adopt a relatively inexpensive configuration in which the engagement state between the clutch pawl and the clutch pawl is set so as not to be changed unless the artificial operation pedal is operated to the limit. In addition, as a power conversion mechanism that changes the push-and-pull operation of the Bowden wire by the artificial operation pedal into the rotation of the input shaft as in claim 3, a general device rack and pinion is adopted, and the artificial operation pedal It would be more convenient if the rotational movement amount of the ratchet by stepping on is slightly larger than the circumferential interval between adjacent clutch claws in the circumferential direction, and a configuration that operates reliably with an inexpensive configuration is adopted.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of an artificial drive type binding tool according to the present invention and a manually driven stationary type binding device using the same will be described below with reference to the drawings. FIG. 1 is an overall view showing an example of how to use it as a human-powered stationary binding device, FIGS. 2 to 6 are views relating to a tool body, FIGS. 7 to 11 are views relating to a human power pedal device as a power supply unit, FIGS. 12 to 19 are operation diagrams showing the general operation status of each step of binding in the tool body, FIG. 20 is a plan view of a partially cut-out showing a conventional binding tool built in an electric motor, and FIGS. It is each figure which shows the structure of an incomplete binding prevention means.

[Example 1]
As shown in FIG. 1, an artificially driven binding tool A according to the present invention includes a tool body H for performing a series of binding operations for sending a binding band 1 and winding it around a binding target W and tightening and binding it, and a tool. An artificial power unit K that is separate from the tool main body H that can supply the driving force necessary for performing a series of bundling operations to the main body H, and the power generated in the artificial power unit K to the power input unit n of the tool main body H And a transmission mechanism D for transmission.

  The state shown in FIG. 1 is a manpower driven stationary binding device G using the artificially driven binding tool A, and the tool body H is mounted on the support portion 3 and mounted on a work table (working table). 2) and the artificial power unit K is configured as a human power pedal device having an artificial operation pedal 4 to be stepped on. The transmission mechanism D is configured by providing a Bowden wire 5 that interlocks and connects the human power pedal device K and the power input unit n. That is, the worker M sitting on the work chair 6 sets the binding object W such as a wire harness in the binding space S sandwiched between the pair of upper and lower flange members 7 and 8 in the tool body H using both hands. By stepping down the artificial operation pedal 4 in this state, the binding object W can be bound with a predetermined binding pressure using the binding band 1 (described later). Reference numeral 9 denotes a rotating reel supported by the tool body H in order to continuously supply the binding band 1 to the tool body H.

  The tool main body H uses a known electric automatic binding tool (see FIG. 20) B having a built-in electric motor 47 as a drive source (power source), and various mechanisms necessary for the binding operation remain as they are. In this case, only the electric motor and its drive circuit, sensors, switches, wiring, and other related parts of the electric drive unit are omitted, and instead, a power input unit n is provided to accept external power. It is comprised as an external power type binding tool. Thus, the system which can reduce the cost required as the binding tool A to about a half is realized by changing an electric drive type into a manpower drive type. Next, the structure of each part constituting the artificial drive type binding tool A will be described in detail.

  As shown in FIGS. 2 to 6, the tool body H includes a rotating reel 9 (see FIG. 1), a feeding mechanism a, a body body 10 having a grip portion 11 on the lower side for gripping and supporting with a finger. While equipped with a heel opening / closing mechanism b, a tightening mechanism c, and a cutting mechanism d, it has a power input portion n configured on the left side surface of the main body 10. In addition, about locations other than the power input part n, it will be well-known and shall be stopped to outline description. In the main body 10, a counter shaft 12 that accelerates and inputs rotational power from the power input unit n, a cam shaft 13 that meshes with the counter shaft 12 and is driven to rotate at a reduced speed, and is driven by the cam shaft 13. The feed shaft 14 and the cam 15 attached to the left end of the cam shaft 13 are provided. One cycle of the bundling operation described later is configured to be performed while the counter shaft 13 is rotated once.

  The rotary reel 9 is pivotally supported around a front and rear axis (not shown) at a position above the main body 10 by front and rear stays 10s, and although not shown, a number of binding bands 1 are arranged in parallel. A tie band is formed by being wound around. In other words, the unrolling reel 9 is unwound and rotated, so that the detection band 1 can be sequentially supplied from the wound binding band to the upper end of the main body 10.

  As shown in FIGS. 13 and 14, the delivery mechanism “a” includes a band 1 </ b> V and a binding band 1 having a band 1 </ b> V and a head 1 </ b> H through which the band 1 </ b> V can be inserted in a reversely restricted state. An example of an object) A long length made of a flexible material that can be bent and displaced from a supply position s (see FIG. 14) to a delivery completion position k (see FIG. 14) for winding around W. -Like spiral 16, a gear-like ring body 17 having a tooth part 17 a meshing with the tooth part 16 a of the spiral 16, an input gear 18 engaged with the gear-like ring body 17, and a short rack 19 meshing with the input gear 18. In addition, it is configured to have an interlocking link 21 or the like that spans between the distal end portion of the drive arm 20 attached to the camshaft 13 and the short rack 19.

  As shown in FIG. 12 and the like, the heel opening / closing mechanism b includes an upper heel member 7 disposed on the top end of the main body 10 so as to be swingable around the first fulcrum P1 (see FIG. 17), and a second fulcrum P2. A lower collar member 8 is provided at the lower end of the front end of the main body 10 so as to be swingable around (see FIG. 15). A pair of binding band guides 7 and 8 arranged opposite to each other in the vertical direction are moved away from each other in order to take the binding target W into a binding space S formed between the upper and lower sides of the binding members 7 and 8. It is possible to switch between an open posture (see FIG. 12) and a first closed posture (see FIG. 13) and a second closed posture (see FIG. 16) in which both the members 7 and 8 are close to each other.

  As shown in FIG. 13, the first closed posture is a posture in which only the upper collar member 7 swings downward and the tips of the collar members 7 and 8 are in close contact with each other (the lower collar member 8 is still in the standby position). And a state suitable for winding the binding band 1 sent out by the sending mechanism a around the binding object W taken in the binding space S is formed. As shown in FIG. 15, the second closed posture is a posture in which the lower collar member 8 is swung upward and swinging within a predetermined range in the first closed posture, and the operation from the first closed posture to the second closed posture is performed. The band portion 1V whose tip is close to the head portion 1H can be inserted into the head portion 1H (band insertion step).

  As shown in FIGS. 14 to 16, the tightening mechanism c forcibly applies the band front end 1v through which the head 1H is inserted in the band 1V to tighten the band 1V wound around the binding object W. A tightening drum 23 that is driven and rotated by the camshaft 13 via the intermediate gear 22, and a pair of front and rear rotatable clamping drums 24 and 25 that are disposed close to each other above the tightening drum 23. Is provided. In other words, the band tip 1v sent when the heel opening / closing mechanism b is in the second posture reaches between the tightening drum 23 and the first clamping drum 24 that are always driven to rotate, so that the band tip 1v is pulled into the tightening mechanism c and is sent obliquely downward from between the tightening drum 23 and the second clamping drum 25, so that the tightening operation by pulling the band portion 1V can be performed in an instant. It is configured.

  As shown in FIG. 17, the cutting mechanism d includes a vertically-facing cutter (cutting blade) 26 provided in the front end portion of the main body 10 immediately above the root portion of the lower collar member 8, and both upper sides of the cutter 26. And a drive lever 27 swingable about the first fulcrum P1 in the engaged state. That is, the cutter cam 28 attached to the camshaft 13 kicks the drive lever 27 and lifts and swings the cutter 26 so that the cutter 26 moves upward, and the band portion 1V after the tightening is completed is positioned at the intermediate position of the head portion 1H. It is configured to cut. The cut surplus band portion 1y is dropped and stored in the collecting portion 29 formed in front of the grip portion 11.

  2 to 5, the power input unit n is for transmitting the power generated in the human power pedal device K to the counter shaft 12 via the Bowden wire 5, and the inner cable 5A of the Bowden wire is connected to the power input unit n. A rack and pinion 32 is provided that includes a rack gear 30 having a freely connectable tip and a pinion gear 31 that meshes with the rack gear 30, and converts the movement of the inner cable 5 </ b> A into the outer cable 5 </ b> B into the rotational movement of the pinion gear 31. And a compression coil spring 33 for returning and urging the inner cable 5A in the direction of being pulled out from the outer cable 5B. The input shaft 34 having the pinion gear 31 is provided with a large gear 36 that meshes with the small-diameter gear 35 of the counter shaft 12, and is configured to amplify the sliding movement amount of the rack gear 30 and rotationally drive the counter shaft 12. ing.

  A rail bracket 37 is fixed to the left side surface of the main body 10. The rail bracket 37 is formed of a plate material that has a horizontally long U-shape when viewed from the side. Has been. On the tip side of the rail bracket 37, a tip spring seat 39 is slidable forward and backward with the rail protrusions 39a and 39a fitted in the upper and lower rail grooves 38, 38. The tip spring seat 39 and the base side are provided. A compression coil spring 33 is provided between the fixed spring seat 40 and the fixed spring seat 40. The base side end of the rack gear 30 is bolted to the support portion 39b on the front side of the tip spring seat 39, and when the inner cable 5A is pulled, the compression coil spring 33 is compressed against its elastic force to compress the rack gear 30. Can be slid in the retracting direction, and if the tension of the inner cable 5A is released, the rack gear 30 can be slid by the elastic force of the compression coil spring 33 and can be self-returned to the starting end position.

  That is, as shown in FIGS. 4 to 6 and FIG. 21, the power input unit n forcibly rotates the input shaft 34 in a predetermined direction by one of the push-pull movements by the Bowden wire 5, and push-pull It has a power conversion mechanism E with a one-way clutch Cr that functions so that the input shaft 34 does not rotate depending on the other movement. As a result, the pinion gear 31 rotates integrally with the large gear 36 (with the input shaft 34) in the direction of arrow A (see FIG. 4), and only the pinion gear 31 rotates in the direction of arrow B (see FIG. 4). As shown in FIG. 6, the one-way clutch Cr includes a housing 41 that is bolted to the pinion gear 31, a clutch rotating body 42 that is fitted in the pinion gear 31 and the housing 41 in a state of rotating integrally with the input shaft 34, and a housing 41 includes a ratchet 43 pivotally supported in 41, and a torsion spring 44 that elastically biases the ratchet 43 in a direction to engage the clutch pawl 42a on the outer periphery of the clutch rotating body 42.

  As a reference, FIG. 20 is a plan view showing a schematic internal structure of a conventional binding tool B driven by an electric motor 47. In the electric binding tool B, the counter shaft 12 and the motor shaft 47a are interlocked and connected via a bevel gear mechanism 61, and the counter shaft 12 does not protrude to the outside. On the other hand, in the external drive type binding tool A according to the present invention, as shown in FIG. 5, the counter shaft 12 is extended to protrude leftward from the tool body H, and is engaged with the small diameter gear 35 at the protruding end. An input shaft 34 having a gear 36, a rack and pinion 32 for rotating the input shaft 34 by the Bowden wire 5 and the like are arranged between the tool body H and the cover frame 62, and a power input unit n is newly constructed. However, the electric motor 47 is omitted.

  Next, the human power pedal device K which is a power supply unit will be described. As shown in FIGS. 7 to 11, the manual pedal device K includes a swing pedal (an example of an operated tool) that is pivotally supported by a base member 48 so as to be freely lowered and swung by stepping and raised and swung by release of stepping. ) 4, a movable member 45 supported by a vertical frame 49 standing on the base member 48 so as to be slidable up and down, and an interlocking mechanism 46 similarly supported by the vertical frame 49 so as to be slidable up and down. Configured.

  The base member 48 is made of a steel plate whose left and right ends are bent upward to be reinforced, and a pair of left and right insertion holes 48a and 48a for pivotally supporting the swing pedal 4 are formed on the base side thereof. . The swing pedal 4 is made of a steel plate press having a transverse cross-sectional shape of a downward U-shape and a support shaft 4a supported at both ends in the insertion holes 48a, 48a of the base member 48. A relief notch 4 </ b> A having a rectangular recess shape is formed at the left and right central portions on the distal end side.

  The vertical frame 49 includes a bottom plate 49A, a right vertical wall member 49B, a left vertical wall member 49C, and a front wall member 49D that are fixed to the tip side portion of the base member 48. The movable member 45 accommodated in the vertical frame 49 is formed by the right vertical groove 49b formed on the inner side and the left vertical groove 49c formed by a clearance in the front-rear direction between the left vertical wall member 49C and the front wall member 49D. Is supported so that it can be slid up and down. The movable member 45 includes a hook hole 45a for pivotally supporting the drum portion 5a at the tip of the inner cable 5A of the Bowden wire 5, a recess 45b formed on the side surface to form a torque limiter Tr (described later), It is formed of a square block having a pair of left and right shaft projections 45c and 45c for sliding into the left vertical grooves 49b and 49c. That is, the vertical frame 49 is formed with a support portion Si for receiving the outer cable 5B, and the movable member 45 is formed with a connecting portion Re for connecting the inner cable 5A.

  The interlocking mechanism 46 includes a pair of left and right contact members 50a and 50a made of a shaft member, a bottom member 50b, a square tube space 50c for accommodating a spring, and a pair of left and right sliding rails 50d that are vertically long. , 50d, a compression-type coil spring 51, a clutch member 52 and the like mounted on the tip side of the coil spring 51, and a load in a driving direction more than a predetermined level is applied to the movable member 45. In addition, a torque limiter Tr that cuts off the linkage between the swing pedal 4 and the movable member 45 is provided.

  The intermediate body 50 has its left and right vertical rail protrusions 50d and 50d fitted in left and right slide grooves 49d and 49d formed on the inner surface side of the vertical frame 49, so that the intermediate frame 50 can slide up and down within a predetermined range. When the swing pedal 4 is stepped on, the pedal short wall 4b formed side by side on the left and right sides presses the left and right contact members 50a and 50a to forcibly slide downward. It is configured to be. The clutch member 52 that is forwardly biased by the coil spring is positioned inside the vertical frame 49, and a rotatable roller 52 a that is pivotally supported by the distal end portion of the clutch member 52 presses the concave portion 45 b of the movable member 45. It is set to fit in.

  The concave portion 45b has a substantially semicircular shape in side view so as to follow the outer shape of the roller 52a, and the lower end portion thereof is formed on an inclined surface 45d that is cut obliquely downward. That is, as shown in FIG. 10, the movable member 45 and the intermediate body 52 are normally in a state of sliding up and down integrally, and as the swing pedal 4 is depressed, the intermediate body 52 and the movable member 45 move downward together. As a result, the inner cable 5A is forcibly pulled. When the inner cable 5A is pulled, the rack and pinion 32 of the power input unit n is actuated and the input shaft 34 is rotationally driven in the direction of the arrow (see FIG. 4).

  However, an excessive load is applied to the driving portion of the tool body H or the Bowden wire 5, that is, the pressing force of the movable member 45 due to some cause, such as foreign matter having an unexpected size between the upper and lower flange members 7 and 8. 11, the component force that pushes back the clutch member 52 to the intermediate body 50 side (in the direction of the arrow C in FIG. 11) due to the contact between the roller 52 a and the inclined surface 45 d is applied to the coil spring 51 as shown in FIG. 11. As a result, the roller 52a comes out of the recess 45c and only the intermediate body 50 slides downward, so-called “empty step state”. Therefore, if the swing pedal 4 is depressed with a large operating force without noticing the trouble, the torque limiter Tr is automatically operated so that a pressing force exceeding a predetermined value is not transmitted to the movable member 45. As a result, the drive of the tool body is interrupted to prevent failure.

  That is, the torque limiter Tr is a movable member of the movable member 45 and the intermediate member 50 that is movable along the moving direction of the movable member 45 and is forced to move downward by the swing pedal 4 (whichever One example) of the intermediate body 50 and the movable member 45 in a state of being protruded and biased by a coil spring (an example of an elastic mechanism) 51 so as to be fitted into the recess 45b, and a recess 45b formed on the side wall of 45. Clutch member 52 supported by intermediate member 50 (an example of one of the other), and when the load in the driving direction (in the direction of arrow D in FIG. 11) acting on movable member 45 is below a predetermined value, the clutch When the member 52 is fitted in the recess 45b and the intermediate body 50 and the movable member 45 move integrally, and the load in the driving direction acting on the movable member 45 exceeds a predetermined value, the member 52 is provided in the recess 45b. Clutch member 52 by the force pushing back the clutch member 52 to the intermediate member 50 is greater than the projecting energizing force of the coil spring 51 is set to a state to get out of the recess 45b by the component force by the inclined surface 45d was.

  When the torque limiter Tr is actuated and is in an idling state, first, an operation for eliminating a trouble such as removing a foreign object sandwiched between the pair of flange members 7 and 8 is performed. At this time, the rack gear 30 is returned to the standby position by the restoring force of the compression coil spring 33, whereby the inner cable 5A is pulled to act to return the movable member 45 to the standby position where it is raised most. The swing pedal 4 that has been stepped down and lowered is moved upward by, for example, lifting the intermediate body 50 with a finger, and the roller 52a (the clutch member 52) is returned to the normal state where it is fitted in the recess 45c. Thereafter, the stepping operation of the swing pedal 4 is resumed.

  Next, the incomplete binding prevention means F equipped in the power input unit n will be described. The incomplete bundling prevention means F, for example, stops the stepping operation of the swing pedal 4 halfway, and then depresses the swing pedal 4 that has returned to the standby position T0 (see FIG. 21) where it has returned to the upper limit. Even in this case, if the swing pedal 4 is depressed to the lower limit, one cycle of the bundling operation is performed as expected so that the bundling can be performed satisfactorily. And a transmission mechanism D that transmits power to the power input unit n of H, and the operation amount of the artificial power unit K is at a specified level that generates a power amount necessary for performing one cycle of the bundling operation in the tool body H. Only when it has been reached, it is configured to function so that the next bundling operation can be started.

  More specifically, as shown in FIGS. 21 and 22 to 24, the incomplete binding preventing means F is substantially constituted by a one-way clutch Cr. The one-way clutch Cr drives the tool body H by forcibly rotating the input shaft 34 in the direction of the arrow by the downward swing by the depression of the swing pedal 4, and the swing swing of the swing pedal 4 when the foot is released. Depending on the condition, the pinion gear 31 may be idled so that the input shaft 34 does not rotate in any direction and remains stopped. The clutch pawls 42a are separated from each other by 180 degrees on the outer periphery of the clutch rotating body 42. A total of two locations are formed at the same position.

  That is, the power conversion mechanism E is configured by the rack and pinion 32 with the one-way clutch Cr in the artificial drive type binding tool A of the first embodiment. The rack and pinion 32 is configured by disposing the rack gear 30 connected to the inner cable 5A of the Bowden wire 5 and the pinion gear 31 fitted to the input shaft 34 so as to mesh with each other, and the one-way clutch Cr Is constituted by a ratchet 43 pivotally supported on the pinion gear 31 side in an integrally rotated state, and two (a plurality of examples) clutch claws 42a provided on the input shaft 34 side in an integrally rotated state. The incomplete bundling prevention means F is set so that the rotational movement amount of the ratchet 43 due to the most depression of the swing pedal 4 is slightly larger than the circumferential interval between the adjacent clutch claws 42a and 42a. It is configured. That is, the ratchet 43 in the one-way clutch Cr and the clutch pawl 42a that can mesh with the ratchet 43 are changed to different combinations with the upward return movement after the swing pedal 4 is depressed to the limit. It is configured by setting the direction clutch Cr.

  The operation of the power conversion mechanism E will be described. In a state where the swing pedal 4 is not depressed and is in the standby position T0, the rack gear 30 is also in the standby position t0 and the ratchet 43 and the clutch pawl 42a are located on the clutch rotating body 42 as shown in FIG. The positions are slightly separated from each other in the circumferential direction (see the ratchet 43 drawn with phantom lines on the input shaft 34 in FIG. 21). Then, as shown in FIG. 21, the ratchet 43 is moved in the direction of the arrow by the slight movement of the rack gear 30 in the direction of the arrow E due to the slight depression of the swing pedal 4 from the standby position T0 to the start position T1. A starting state (the state shown in FIG. 21 and corresponding to the start point t1 in FIG. 19) is brought into contact with the upper clutch pawl 42a. Note that m shown in FIGS. 21 to 24 is a triangular mark on the drawing showing the reference position of the rack gear 30.

  Further, as the swing pedal 4 is depressed and the rack gear 30 is moved in the direction of the arrow E, the pinion gear 31 rotates in the direction of the arrow and the ratchet 43 rotates in the direction of the arrow to push and drive the clutch pawl 42a. The tool body H is driven by rotating the rotating body 42, that is, the input shaft 34 in the arrow direction. Then, as shown in FIG. 22 (a), the clutch rotating body 42 and the input shaft 34 are moved to the limit of the rack gear 30 accompanying the depression of the swing pedal 4 to the lower end position T2, that is, drawn to the finish point t2. Is rotated 180 degrees from the start state, and one cycle of the binding operation is performed.

  As shown in FIG. 22 (b), the rack gear 30 at the finish point t2 moves in the direction of the arrow to move the start point t1 as the stepping is released and the swinging pedal 4 returns to the standby position T0 where the pedal is fully raised. When returning to the slightly standby position t0, the pinion gear 31 and the ratchet 43 are rotated back 180 degrees in the direction of the arrow from the position shown in FIG. 22 (a), and overrun the other clutch pawl 42a. It returns to the standby state where it stops. The interval between the start point t1 and the standby position t0 is a slight allowance, and the next time the swing pedal 4 is depressed, the ratchet 43 reliably drives the clutch pawl 42a in the direction of the arrow (see FIG. 21). It can be done. In other words, the clutch pawl 42a is formed at two locations in the circumferential direction of the clutch rotating body 42 so that the input shaft rotates exactly once by the two pulling movements of the rack gear 30 and thereby the two cycles of the bundling operation are performed. Yes.

  Next, a case will be described in which the depression of the swing pedal 4 is interrupted for some reason, the depression is released, and the depression is performed again. As shown in FIG. 23 (a), from the start state shown in FIG. 21, for example, the depression of the swing pedal 4 is interrupted or released at a midway position T3 where the input shaft 34 rotates approximately ¼ in the arrow direction. Then, the clutch rotating body 42 stops rotating at that position (a position corresponding to the rack gear 30 at the midway position t3). On the other hand, the rack gear 30 at the midway position t3 returns to the standby position t0 by the urging force of the compression coil spring 33 as shown in FIG. 23 (b) when the swing pedal 4 at the midway position T3 is released. It becomes like this. In this state, the clutch rotating body 42 is at a rotational position corresponding to the midway position t3 of the rack gear 30, and the ratchet 43 has returned to the initial position (see FIG. 22B) corresponding to the standby position t0.

  Then, when the swing pedal 4 that has returned to the highest position is depressed again to move the rack gear 30 (see FIG. 23 (b)) at the standby position t0 in the direction of arrow E, the ratchet 43 is moved to the clutch pawl 42a. Until the contact, the clutch rotating body 42 remains stopped, and only the pinion gear 31 rotates, as shown in FIG. After the ratchet 43 comes into contact with the clutch pawl 42a, the ratchet 43 returns to the state of pushing and driving the clutch pawl 42a, and the pinion gear 31 rotates together with the clutch rotating body 42. FIG. 24A shows the state immediately before the swing pedal 4 that has been stepped on again from the standby position T0 returns to the midway position T3.

  When the swing pedal 4 is depressed again to the lower end position T2, as shown in FIG. 24B, the clutch pawl 42a is the same as when the swing pedal 4 is normally depressed to the lower limit. Even if the stepping operation is interrupted and then stepped on again, the binding tool H performs a regular one cycle of the binding operation as a result. In short, by providing only one clutch pawl 42a during the half rotation of the clutch rotating body 42 necessary for performing one cycle of the bundling operation, that is, in the half section of the outer periphery of the clutch rotating body 42. (The clutch pawl 42a is formed in two places on the clutch rotating body 42). Even when the swing pedal 4 is returned and the pinion gear 31 is rotated in the reverse direction while depressing, the pinion gear 31 is moved away from the one clutch pawl 42a in the reverse direction. This is due to the fact that the ratchet 43 is configured so as not to get over the other clutch pawl 42a.

  For example, when the clutch pawl 42a is formed on the clutch rotating body 42 at five positions at equal angles in the circumferential direction, the pinion gear 31 rotates 1/4 (90 degrees) as shown in FIG. Then, when it is returned to the original position, the front clutch pawl 42a, which is 72 degrees apart in the circumferential direction, gets over in the reverse direction, and then when the swing pedal 4 is normally depressed, the pinion gear 31, that is, the input shaft 34 Is rotated more than 1/2 rotation, and the state in which the bundling operation is performed for one cycle or more becomes the starting point of the next operation, and there is a disadvantage that the bundling becomes substantially impossible. On the other hand, in the configuration of the present invention in which only one clutch pawl 42a is provided with respect to the rotation angle of the clutch rotating body 42 required for one cycle of the bundling operation, such inconvenience does not occur. No matter how many times the operation of interrupting the swing pedal 4 is repeated, the input shaft 34 is rotated only as much as necessary to perform one cycle of proper bundling operation by stepping down to the lower end position T2. It has been devised so that the binding work can be continued well.

  Next, one cycle of the bundling operation by stepping on the swing pedal 4 will be schematically described. The externally driven binding tool A is a known tool that can perform a one-cycle binding operation by one stepping operation of the swing pedal 4, and the operation process is roughly divided into a binding band supply process and a binding space. It consists of a closing process, a bundling band feeding process, a head part insertion process, a band tightening process, and a surplus band cutting process. It should be noted that one cycle of bundling is set to be performed all while the cam 15 (cam shaft 13) rotates exactly once.

  The binding band supply step is a step of supplying the binding band 1 supplied from the rotary reel 9 or the like to the band loading unit 56 in the upper part of the tool main body H. That is, as shown in FIG. 12A, the rack gear 30 is pulled in accordance with the depression of the swing pedal 4, moves in the direction of arrow E, the input shaft 34 rotates by a predetermined angle in the direction of arrow A, and the counter shaft 34 moves in the direction of the arrow. The cam shaft 13 and the cam 15 start to rotate in the arrow direction from the standby position (position shown in FIG. 12A). Then, as shown in FIG. 12B, when the cam 15 rotates in the direction of the arrow, the intermediate link 53 rotates in the direction of the arrow H to cause the vertical rack member 54 to slide down and engage with the rack gear portion 54a. A band winding drum 55 having a passive gear portion 55a that rotates is unrolled from the rotating reel 9 provided above the tool body H and wound around the drum 55 (illustrated). (Omitted), one binding band 1 is supplied to the band loading section 56 of the tool body H. Note that the binding band 1 drawn with imaginary lines is scheduled to be used in the next binding cycle.

  The bundling space closing step is a step in which the upper collar member 7 is swung downward to swing the bundling space S into a closed space. That is, as shown in FIG. 13, the cam shaft 13 and the cam 15 further rotate in the direction of the arrow at a predetermined angle, whereby the tool body internal side portion (not shown) of the upper collar member 7 and the cam shaft 13 rotate integrally. The upper collar member 7 moves downward and swings along the arc-shaped rail portion 57 of the tool main body H by an interlocking mechanism (not shown) with the upper guide cam that is not operated, and the lower edge member 8 whose tip is fixed. The bundling space S is closed by contact with the tip portion of the wire. As a result, the binding object W taken into the binding space S is prevented from coming out of the binding space S, and a state in which the binding band 1 is ready to be wound is brought about. In this case, the spiral 16 which is a member for pushing the binding band 1 is started to move from the standby position by the feeding mechanism a that is always driven, and as shown in FIG. 13, the binding band 1 of the band loading unit 56 is Slightly pushed forward.

  The binding band sending process is a process of pushing out the spiral 16 to send the binding band 1 from the supply position s to the completion position k. As shown in FIG. 14, the spiral 16 is formed in a belt-like shape made of a soft synthetic resin material (a material having flexibility) with teeth 16a formed on the entire inner surface thereof. The spiral wheel accommodated in the accommodation cylinder 58 (see FIGS. 18 and 19) is driven by the camshaft 13 through the interlocking link 21 and the drive arm 20 to rotate the gear-like ring body 17 having the teeth 17 a to be engaged. It is comprised so that 16 can be forcedly moved.

  That is, when the cam 15 (cam shaft 13) is further rotated in the arrow direction, the rotational speed of the gear-shaped ring body 17 by the feed mechanism a that is always driven is increased in the rotation angle range. Thus, the spiral 16 is rapidly pushed out, and the binding band 1 can be quickly delivered and pushed out to the completion position k. In the state of being delivered to the delivery completion position k, as shown in FIG. 14, the band portion 1V is guided by the respective guide grooves (not indicated) formed on the inner surfaces of the upper and lower flange members 7 and 8. The band portion 1V is wound and moved so as to surround the binding object W, and is set to be positioned immediately next to the head portion 1H.

  The head portion insertion step is a step of inserting the band portion 1V, the tip portion of which is located immediately beside the head portion 1H, into the head portion 1H. That is, as shown in FIG. 15, the cam 15 (cam shaft 13) is further rotated by a predetermined angle, whereby the operating fork 59 interlocked and linked by a structure (not shown) can rotate at the fulcrum P2 in the lower eaves member 8 Acts on the end portion of the base side and lifts and swings. At this time, since the position of the upper collar member 7 is fixed, the band portion 1V whose circumferential length as the bundling space S, which is a closed space, is inserted through the insertion hole 1h of the head portion 1H from the distal end portion, It is pushed out until it is stuck between the tightening drum 23 and the first clamping drum 24. At this time, the delivery mechanism a starts to return, and the spiral 16 is slightly moved back from the delivery completion position.

  The band tightening step is a step of pulling the tip portion of the band portion 1V through the head portion 1H and winding it tightly around the binding object W without slack. That is, as shown in FIG. 16, the first and second sandwiching drums 24 and 25 are pressed and urged by the elastic drum 60 against the tightening drum 23 that is always rotated. The band portion 1 </ b> V that reaches between the tightening drum 24 and the tightening drum 23 is instantaneously pulled by the tightening mechanism c, and is pulled by being sandwiched between the second clamping drum 25 and the tightening drum 23, and the direction of the tilt is inclined from the lateral direction. Sent in a state changed downward. Since this tightening process is performed instantaneously by using the tightening drum 23 that rotates at a high speed, the cam 15 (cam shaft 13) rotates very little from the position shown in FIG. 15, and accordingly, FIGS. However, the parts other than the binding band 1 are drawn as the same for convenience.

  The surplus band cutting step is a step of cutting off the surplus band portion that protrudes beyond the head portion 1H in the band portion 1V. That is, as shown in FIG. 17, the tool body H in the vicinity of the fulcrum P2 of the lower collar member 8 is provided with the above-described cutting mechanism d having the cutter 26 that can move up and down in a vertical orientation, and the band tightening step. At substantially the same time as the end of the operation, the cutter cam 28 pushes up the drive lever 27, so that the cutter 26 moves upward and cuts the band portion 1V in the vicinity of the head portion 1H. After cutting, the surplus band portion 1y is dropped and collected by the collection unit 29. At this time, the upper collar member 7 swings up and down, and the lower collar member 8 swings down and returns to the respective standby positions.

  The cam 15 (cam shaft 13) rotates by a predetermined angle from the end state of the surplus band cutting step (the state shown in FIG. 17), and is bound by the binding band 1 while making a slight one turn from the standby position as shown in FIG. The binding object W is moved from the binding space S to the outside, the sending mechanism a is returned, and the spiral 16 is accommodated inside the tool body H in a state where most of the spiral 16 is inserted into the accommodating cylinder 58. Move back to the standby position. Then, when the vertical rack member 54 is moved upward toward the original standby position by being kicked by the paper 12A to drive the passive gear portion 55a in the reverse rotation direction, the one-way clutch ( With the function (not shown), the drum 55 (see FIG. 12) remains stopped. The cutter 26 is moved downward.

  Then, when the cam 15 (cam shaft 13) is rotated once, as shown in FIG. 19, each part returns to the standby state shown in FIG. 12 (a) to prepare for the next bundling operation. The movement stroke L of the rack gear 30 required for one cycle of this bundling is the distance between the start point t1 and the finish point t2 located immediately above the axis of the input shaft 34 in each rack gear 30 in FIGS. Is defined as And the raising / lowering movement stroke of the movable member 45 in the operating manual power pedal apparatus K is set so that the movement stroke L of the inner cable 5A may be produced.

  As described above, in the externally driven binding tool according to the present invention and the manually driven stationary binding device using the same, the conventional electric motor, its drive circuit and other electrical components and electrical related mechanisms are completely excluded. Since the tool main body is driven by human power using the swing pedal 4, more specifically, leg force, a series of binding the binding object W with the binding band 1 in the binding space between the pair of flange members 7 and 8. The bundling operation can be performed mechanically and conveniently, while the cost can be greatly reduced and the cost can be reduced. As a result, it is possible to construct a bundling tool that mechanizes bundling work that is too labor intensive and poor in work efficiency, and can be constructed at a low cost. It can be introduced without difficulty in countries and the like, and it is possible to improve the efficiency of bundling work.

Overall view showing an example of using a bundling tool as a manually driven stationary bundling device Exploded perspective view showing the structure of the power input section of the tool body, part 1 Exploded perspective view showing the structure of the power input part of the tool body, part 2 Side view of tool body Plan view of part of the tool body Exploded perspective view showing the structure of the one-way clutch Overall perspective view of the pedal pedal device Exploded perspective view showing the structure of the pedal pedal device Partial perspective view of the pedal pedal device Side view during the stepping operation showing the normal operating conditions Side view during the stepping operation showing the operating status during overload Action diagram showing the binding band supply process Action diagram showing the process of closing the binding space by lowering the upper arm Action diagram showing the binding band delivery process Operational diagram showing the band head insertion process by raising the lower armpit Action diagram showing the tightening process of the cable tie Action diagram showing cutting process of surplus band Action diagram showing spiral return process Side view showing the tool body returned to the standby state Partially cutaway plan view showing the schematic structure of a conventional bundling tool with a built-in electric motor Partially cutaway side view of the main part showing the structure of incomplete binding prevention means (A) is an operation diagram showing the power input unit when the swing pedal is fully depressed, and (b) is an operation diagram showing the power input unit in a state where the swing pedal is raised and returned. (A) is an operation diagram showing the power input unit when the swing pedal is stopped at a midway position, and (b) is an operation diagram showing the situation of the power input unit after the swing pedal is released from being depressed. (A) is an operation diagram showing the power input unit when the swing pedal is being re-depressed, and (b) is an operation diagram showing the power input unit when the re-depressing operation of the swing pedal is completed.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Binding band 4 Artificial operation pedal 5 Bowden wire 5A Inner cable 30 Rack gear 31 Pinion gear 32 Rack & pinion 34 Input shaft 42a Clutch claw 43 Ratchet n Power input part Cr One-way clutch D Power transmission mechanism E Power conversion mechanism F Incomplete binding prevention means H Tool body K Artificial power part W Binding target

Claims (3)

  A tool body for performing a series of bundling operations for sending out a bundling band and winding it around a bundling target and tightening and bundling, and for supplying power necessary for performing the bundling operation to the tool body by manual operation An artificial power unit configured separately from the tool body, and a transmission mechanism that transmits power generated in the artificial power unit to a power input unit of the tool body. An imperfection that functions so that the next bundling operation can be started only when the operation amount reaches a prescribed level that generates the amount of power necessary to perform one cycle of the bundling operation in the tool body. Artificial drive type bundling tool equipped with bundling prevention means. The artificial power unit is configured as a human-powered pedal device having a manual operation pedal that can be freely moved downward by stepping and can be moved up and returned by releasing the stepping.
The transmission mechanism is configured to have a Bowden wire that transmits push / pull power by the artificial operation pedal to the power input unit,
The power input unit forcibly rotates the input shaft in a predetermined direction by one of the push-pull movements by the Bowden wire, and prevents the input shaft from rotating by the other movement of the push-pull. It has a power conversion mechanism with a functioning one-way clutch,
The incomplete bundling preventing means is changed to a combination in which the ratchet in the one-way clutch and the clutch pawl that can mesh with the ratchet are different from each other in accordance with the ascent return movement after depressing to the limit of the artificial operation pedal. The artificial drive type binding tool according to claim 1, wherein the one-way clutch is set so that the one-way clutch is set. The power conversion mechanism is configured as a rack and pinion that is configured so that a rack gear coupled to an inner cable of the Bowden wire and a pinion gear fitted to the input shaft are engaged with each other, and the one-way clutch Is composed of a ratchet pivotally supported on the pinion gear side in an integrally rotating state and a plurality of clutch claws provided on the input shaft side in an integrally rotating state,
The incomplete bundling prevention means is configured by setting a rotational movement amount of the ratchet due to the most depression of the artificial operation pedal to be slightly larger than a circumferential interval between the adjacent clutch claws. The artificial drive type binding tool according to claim 2.

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