DE102019120637A1 - Structural steel tie tool - Google Patents

Abstract

A structural steel binding tool disclosed herein may include a spool that includes a wire, a wheel that holds the spool and is integrally rotatable with the spool, a wheel holder that rotatably holds the wheel, and an elastic body that extends between the Wheel and the tool holder is inserted. Another structural steel binding tool disclosed herein may include a spool that includes a wire, a wheel that holds the spool and is integrally rotatable with the spool, and a wheel holder that rotatably holds the wheel. The wheel can be movable relative to the wheel holder.

Description

TECHNICAL AREA

The technique disclosed herein relates to a structural steel binding tool (reinforcement connector, also known as a toggle machine).

BACKGROUND

Japanese Patent Application Publication No. 2018-111960 discloses a structural steel binding tool. This structural steel binding tool is provided with a spool that has a wire, a wheel that holds the spool and is rotatable integrally with the spool, and a wheel holder that rotatably holds the wheel.

SUMMARY

In the technique of Japanese Patent Application Publication No. 2018-111960, the spool and the wheel are engaged with each other because the spool is pressed against the wheel, whereby the spool and the wheel rotate integrally. With such a configuration, if the spool is excessively pressed against the wheel for any reason, the resistance increases when the spool and wheel rotate. In such a condition, an excessive load can be applied to an actuator pulling the wire out of the spool. The disclosure herein provides a technique for smoothly spinning a spool in a structural steel binding tool in which the spool and a wheel rotate integrally. Furthermore, the disclosure herein provides a technique for suppressing excessive load application to an actuator that pulls a wire from the spool.

A structural steel binding tool disclosed herein may include a spool that includes a wire, a wheel that holds the spool and is integrally rotatable with the spool, a wheel holder that rotatably holds the wheel, and an elastic body that extends between the Wheel and the wheel holder is arranged.

According to the configuration described above, even if the spool is excessively pressed against the wheel for some reason, the elastic body suppresses the excessive pressing force from being applied to the spool and the wheel. Because of this, resistance when rotating the spool and the wheel can be restricted from increasing. Furthermore, excessive load application to an actuator pulling the wire from the spool can be prevented.

Another structural steel binding tool disclosed herein may include a spool that includes a wire, a wheel that holds the spool and is rotatable integrally with the spool, and a tool holder that rotatably holds the wheel. The wheel can be movable relative to the wheel holder.

According to the configuration described above, even if the spool is excessively pressed against the wheel for any reason, excessive pressing force on the spool and on the wheel can be suppressed by moving the wheel relative to the wheel holder. Resistance when rotating the spool and the wheel can be prevented from rising. Furthermore, excessive load application to the actuator pulling the wire from the spool can be prevented.

list of figures

• 1 Fig. 3 is a perspective view showing a structural steel binding tool 2 shows an embodiment from an upper left rear side.
• 2 Fig. 3 is a perspective view showing the structural steel binding tool 2 shows the embodiment from an upper right rear side.
• 3 Fig. 3 is a perspective view showing an internal structure of a binding tool body 4 of the structural steel binding tool 2 shows the embodiment from the upper right rear side.
• 4 Fig. 3 is a perspective view showing the internal structure of the binding tool body 4 of the structural steel binding tool 2 shows the embodiment from an upper left front side.
• 5 Fig. 3 is a perspective view showing a coil accommodating chamber 20 of the structural steel binding tool 2 shows the embodiment from the upper left rear side.
• 6 is a cross-sectional view of a take-up mechanism 36 of the structural steel binding tool 2 the embodiment.
• 7 is a perspective view of a wire spool WR , a turntable 60 and a magnetic sensor 66 of the structural steel binding tool 2 the embodiment from the upper right rear side.
• 8th is a perspective view showing the wire spool WR of the structural steel binding tool 2 shows the embodiment from the upper right rear side.
• 9 is a perspective view showing the turntable 60 of the structural steel binding tool 2 shows the embodiment from the upper left rear side.
• 10 is a cross-sectional view of the wire spool WR and the turntable 60 of the structural steel binding tool 2 of the embodiment in a state in which engaging protrusions 60c the turntable 60 ride on partitions WRd of the wire spool WR.
• 11 is a cross-sectional view of the wire spool WR and the turntable 60 of the structural steel binding tool 2 of the embodiment in a state in which the engaging protrusions 60c the turntable 60 in openings WRe of the wire coil WR are.
• 12 is a cross-sectional view of a wire spool WR and a turntable 60 of a structural steel binding tool 102 of a comparative example in a state in which engaging protrusions 60c the turntable 60 ride on partition walls WRd of the wire spool WR.
• 13 is a perspective view of a wire spool WR, a turntable 60 and an optical sensor 90 of the structural steel binding tool 2 a variant, seen from the upper right rear side.

DETAILED DESCRIPTION

Representative, non-limiting examples of the present teachings will now be described in detail with reference to the accompanying drawings. This detailed description is only intended to provide those skilled in the art with further details on how to implement preferred aspects of the present teachings, and is not intended to limit the scope of the invention. Furthermore, each of the additional features and teachings previously disclosed may be used separately or in conjunction with other features and teachings to provide improved structural steel binding tools and methods of making and using the same.

Furthermore, combinations of features and steps described in detail above may not be necessary to practice the invention in the broadest sense, and instead are only taught to specifically describe preferred examples of the invention. Furthermore, various features of the representative examples described above and the independent and dependent claims can be combined in ways that are not specifically listed to provide additional useful embodiments of the present teachings.

All of the features disclosed in the description and / or the claims can be considered separate and independent from each other for the purpose of the original disclosure and also for the purpose of limiting the claimed invention regardless of the combination of features in the embodiments and / or the claims. Furthermore, any range or indication of groups of units may disclose any possible intermediate value or subset of units for the purpose of the original disclosure and also for the purpose of limiting the claimed invention.

In one or more embodiments, a structural steel binding tool may include a spool that includes a wire, a wheel that holds the spool and is rotatable integrally with the spool, a wheel holder that rotatably holds the wheel, and an elastic body that is between the wheel and the wheel holder is inserted (arranged).

According to the configuration described above, even if the spool is excessively pressed against the wheel for some reason, the elastic body prevents the excessive pressing force from being applied to the spool and the wheel. Because of this, resistance can be prevented from increasing when the spool and the wheel are rotated. Furthermore, excessive load application to an actuator pulling the wire from the spool can be prevented.

In one or more embodiments, the coil may be provided with an opening that is divided by a partition wall. The wheel may have an engaging protrusion configured to enter the opening and abut the partition wall in a direction in which the spool rotates.

With the configuration described above, in which the partition wall of the spool and the engaging projection of the wheel abut each other in the direction in which the spool rotates, it can be ensured that the spool and the wheel rotate integrally. However, with such a configuration, there may be an event in which the engaging protrusion rides on the partition wall instead of entering the opening when the spool is attached to the wheel. If the engaging protrusion rides on the partition wall, the spool is excessively pressed against the wheel compared to a case where the engaging protrusion enters the opening. According to the configuration described above, since the elastic body is interposed between the wheel and the wheel holder, the elastic body prevents the excessive pressing force from being applied to the spool and the wheel even when the engaging projection rides on the partition wall. Because of this, the resistance when turning the Coil and the wheel rises. Furthermore, the excessive load application to the actuator pulling the wire from the spool can be prevented.

In one or more embodiments, the elastic body can be a compression spring.

Due to the configuration described above, the excessive pressure load application to the spool and the wheel can be effectively suppressed in a case where the spool is excessively pressed against the wheel.

In one or more embodiments, the structural steel binding tool may further include a push mechanism configured to push the spool against the wheel.

According to the configuration described above, even if the spool is excessively pressed against the wheel by the pushing mechanism, the elastic body disposed between the wheel and the wheel holder suppresses (prevents) the excessive pressing force from being applied to the spool and the wheel becomes. Because of this, it can be suppressed that the resistance increases when turning the coil and the wheel. Furthermore, the excessive load application to the actuator pulling the wire from the spool can be suppressed.

In one or more embodiments, the structural steel binding tool may further include a rotation detection mechanism configured to detect the rotation of the wheel relative to the wheel holder.

In a case of detecting the rotation of the spool using the rotation detection mechanism as mentioned above, the spool and the wheel must be securely rotated together. However, if a configuration is used in which the spool is pressed firmly against the wheel to ensure the integral rotation of the spool and wheel, there is a risk that the spool will be pressed excessively against the wheel. According to the configuration described above, even if the spool is excessively pressed against the wheel, the elastic body inserted between the wheel and the wheel holder suppresses the excessive pressing force from being applied to the spool and the wheel. Because of this, it can be suppressed that the resistance increases when turning the coil and the wheel. Furthermore, the excessive load application to the actuator pulling the wire from the spool can be suppressed.

In one or more embodiments, a structural steel binding tool may include a spool that includes a wire, a wheel that holds the spool and is rotatable integrally with the spool, and a wheel holder that rotatably holds the wheel. The wheel can be movable relative to the wheel holder.

Due to the configurations described above, even if the spool is excessively pressed against the wheel for any reason, excessive pressurization of the spool and the wheel is suppressed by the wheel moving relative to the wheel holder. Because of this, it can be suppressed that a resistance increases when rotating the coil and the wheel. Furthermore, excessive load application to an actuator pulling the wire from the spool can be suppressed.

In one or more embodiments, the wheel may be movable relative to the wheel holder in a direction along an axis of rotation of the spool and may be immovable in a direction perpendicular to the axis of rotation of the spool.

If an axis of rotation of the wheel is offset from the axis of rotation of the spool when the wheel moves relative to the wheel holder, the resistance increases when the spool and the wheel are rotated integrally, and the excessive load is applied to the actuator which removes the wire from the Coil pulls, applied. According to the configuration described above, even when the wheel moves relative to the wheel holder, the axis of rotation of the wheel is not displaced from the axis of rotation of the spool, and thus, the resistance can be suppressed when the spool and the wheel are rotated integrally. Furthermore, the excessive load application to the actuator pulling the wire from the spool can be suppressed.

embodiments

A structural steel binding tool (reinforcement connector, toggle machine) 2 of an embodiment will now be described with reference to the drawings. The structural steel binding tool 2 , this in 1 is a power tool for binding a plurality of structural steels R (reinforcement bars, reinforcement meshes, reinforcement bars, reinforcement cages) by means of a wire W.

As in 1 and 2 shown, the structural steel binding tool 2 a binding tool body 4 , a handle 6 that is below the binding tool body 4 is provided for holding by a user, and a battery holder 8th on that below the handle 6 is provided. A battery B can be removably attached to a lower area of the battery receptacle 8th be attached. The battery B is a battery of the sliding type, which is attached to the battery holder 8th can be attached or removed by moving it relative to this. The battery B is, for example, a lithium ion battery, which can be recharged by a charger, which is not shown. If the battery B on the battery holder 8th attached, power from the battery B is the structural steel binding tool 2 fed.

The structural steel binding tool 2 is with a housing 12 intended. The housing 12 is with a left housing 14 , a right housing 16 and a side cover case eighteen intended. As in 1 shown, configured the left housing 14 integrally an outer shape of a left half of the binding tool body 4 , an outer shape of a left half of the handle 6 and an outer shape of a left half of the battery holder 8th , As in 2 shown, configured the right housing 16 integral an outer shape of a right half of the binding tool body 4 , an outer shape of a right half of the handle 6 and an outer shape of a right half of the battery holder 8th , The left case 14 is on the right case 16 fixed by a plurality of screws. The side cover case eighteen configures part of the outer shape of the right half of the binding tool body 4 , The side cover case eighteen is on the right case 16 fixed by a plurality of screws.

A coil storage chamber 20 that are used to hold a wire coil WR (see 3 ) on which the wire W is wound is configured at a rear portion of the binding tool body 4 intended. An upper area of the coil accommodating chamber 20 is through a coil cover 22 covered. The coil cover 22 is on the binding tool body 4 about circular ring-shaped recordings 22a . 22b , which are provided on the left and right side, pivotally mounted. The coil cover 22 is for opening and closing the bobbin holding chamber 20 by pivoting relative to the binding tool body 4 configured with a left-right direction as its pivot axis.

An upper front area of the handle 6 is with a pusher 28 configured to be pushed by a user and a handle latch 30 provided behind the pusher 28 is provided and is configured to switch between a state of pressing the pusher 28 enables, and a state that prevents pressing.

As in 3 and 4 shown is the binding tool body 4 primarily with a control board 34 , a recording mechanism 36 , a feed mechanism 38 , a braking mechanism 40 , a guide mechanism 42 , a cutting mechanism 44 and a twist mechanism 46 intended. The control board 34 is on a lower part of the binding tool body 4 arranged.

The recording mechanism 36 is at the rear of the binding tool body 4 intended. The recording mechanism 36 removably holds the wire spool WR in the spool housing chamber 20 is recorded. The wire spool WR is through the take-up mechanism 36 in the bobbin holding chamber 20 rotatably mounted.

The feed mechanism 38 is on an upper area of the binding tool body 4 arranged in a vicinity of a center thereof in a front-back direction. The feed mechanism 38 is configured to be a feed roll 74 by driving a feed motor 72 for pulling out the wire W from the wire spool WR in the take-up mechanism 36 and for leading the wire W out to the guide mechanism 42 on a front portion of the binding tool body 4 is provided, configured. Operation of the feed motor 72 is through the control board 34 controlled.

The leadership mechanism 42 is at the front of the binding tool body 4 arranged. The leadership mechanism 42 is configured to remove the wire W from the feed mechanism 38 is supplied to the plurality of structural steels R in a loop shape (see 1 ) respectively.

The braking mechanism 40 is near the center of the binding tool body 4 arranged in the front-back direction. The braking mechanism 40 is configured to rotate the wire spool WR according to a timing at which the guide mechanism 38 feeding the wire W stops stopping. The wire coil WR has grooves WRa provided therein with a predetermined angular interval and the brake mechanism 40 stops the rotation of the wire spool WR by a brake component 78 engages with one of the grooves WRa by operating a solenoid 76 brings. Operation of the solenoid 76 is through the control board 34 controlled.

The cutting mechanism 44 is at the front of the binding tool body 4 arranged. The cutting mechanism 44 is configured to cut the wire W while the wire W is wound around the plurality of structural steels R by a cutting edge (not shown) which in cooperation with the twisting mechanism 46 turns to cut.

The twisting mechanism 46 is transverse to an intermediate region of the binding tool body from the front region 4 arranged in the front-back direction. The twisting mechanism 46 has a tick 82 configured to rotate a twist motor 80 advance, step back and turn. The twisting mechanism 46 is configured to hook the wire W wound around the plurality of structural steels R by the hook 82 to hold and twist so that the majority of structural steels R are bound by the wire W. Operation of the twist motor 80 is through the control board 34 controlled.

As in 1 shown when the user uses the mild steel binding tool 2 in relation to the majority of structural steels R and the handle 28 pulls, the structural steel binding tool guides 2 a series of operations of winding the wire W around the plurality of structural steels R through the feed mechanism 38 , the brake mechanism 40 and the guiding mechanism 42 , Cutting the wire W and twisting the wire W wound around the plurality of structural steels R by the cutting mechanism 44 and the twisting mechanism 46 out.

Below is the pickup mechanism 36 described in detail. As in 5 and 6 shown is the pick-up mechanism 36 with a left storage mechanism 48 on the left side of the bobbin holding chamber 20 is provided, and a right storage mechanism 50 provided on a right side of the bobbin receiving chamber 20 is provided.

As in 6 shown is the left storage mechanism 48 with a basic component 52 , a cam component 54 , a shaft component 56 and a compression spring 58 intended. The basic component 52 is on the left case 14 fixed by a plurality of screws. The cam component 54 is arranged such that it passes through the base member 52 penetrates and is through the base component 52 held so that it is slidable in the left-right direction. The cam component 54 is in a cylindrical cover holder 54a provided to the outside of the coil accommodating chamber 20 protrudes. The cover holder 54a stops the recording 22a the coil cover 22 , The recording 22b the coil cover 22 is slidably held by a cylindrical cover holder 18a that in the side cover housing eighteen is provided. As in 5 shown is a cam projection 54b on an outer peripheral surface of the cover holder 54a intended. According to the cam projection 54b the cover holder 54a is a cam protrusion (not shown) on an inner peripheral surface of the receptacle 22a the coil cover 22 intended. As in 6 shown is the shaft component 56 with a cylindrical bobbin holder 56a provided in the direction of the inside of the coil receiving chamber 20 protrudes. The shaft component 56 is on the cam component 54 fixed with a plurality of screws. Because of this, the shaft component 56 integral with the cam member 54 in the left-right direction relative to the base member 52 slide. Furthermore, the shaft component 56 in the right direction (ie toward the inside of the bobbin holding chamber 20 ) by the compression spring 58 by the base component 52 is held, biased. In a normal state are a biasing force of the compression spring 58 , the cam component 54 and the shaft component 56 relative to the base component 52 to the right (ie to the inside of the bobbin holding chamber 20 ). The coil holder is in this state 56a in a shaft receiving groove WRb of the wire coil WR and the cam projection 54b of the cam member 54 presses the cam projection of the receptacle 22a in a closing direction of the coil cover 22 , causing the coil cover 22 is closed. In this state, the bobbin holder bumps 56a slidably against the shaft receiving groove WRb, and thus the wire spool WR becomes rotatable relative to the spool holder 56a held. In this state, the wire coil WR is through the coil holder 56a pushed to the right (ie towards the inside of the bobbin holding chamber 20 ). Then when the user has the bobbin cover 22 against the biasing force of the compression spring 58 opens, the cam projection of the receptacle presses 22a the coil cover 22 the cam projection 54b the cover holder 54a to the left (ie towards the outside of the coil receiving chamber 20 ) when the bobbin cover 22 swings. Because of this, the cam member moves 54 and the shaft component 56 relative to the base component 52 to the left (ie towards the outside of the coil receiving chamber 20 ), and the coil holder 56a comes out of the shaft receiving groove WRb of the wire coil WR. In this state, the user can remove the wire spool WR from the spool accommodating chamber 20 take or insert the WR wire spool into it.

As in 6 shown is the right storage mechanism 50 with a turntable 60 , an inner bearing 62 , an outer camp 64 , a magnetic sensor 66 (please refer 3 ) and a compression spring 68 intended. The turntable is through the right housing 16 about the inner camp 62 and the outer camp 64 held rotatable. Furthermore, the turntable 60 in the left-right direction relative to the inner bearing 62 and the outer camp 64 slidably. The hub 60 will turn to the left (ie towards the inside of the bobbin holding chamber 20 ) by the compression spring 68 biased by that outer bearings 64 is held. The turntable is in the normal state 60 left (ie to the inside of the bobbin holding chamber 20 ) relative to the right housing 16 by the preload force of the compression spring 68 ,

The hub 60 is with a cylindrical bobbin holder 60a that towards the inside of the bobbin holding chamber 20 protrudes a disc-shaped rotation detector 60b that along an inside surface of the coil accommodating chamber 20 is arranged, and a plurality of substantially triangular and flat plate-shaped engagement projections 60c provided that towards the inside of the bobbin receiving chamber 20 (please refer 9 ) project. As in 8th As shown, the wire coil WR has a shaft receiving groove WRc provided near its axis of rotation and a plurality of openings Wre arranged on a radial outside relative to the shaft receiving groove WRc and divided by partition walls WRd in a circumferential direction. The coil holder 60a is configured to enter the shaft receiving groove WRc of the wire spool WR and slidably abut the shaft receiving groove WRc. Furthermore, the engagement projections 60c configured to enter the openings WRe of the wire coil WR. When the wire spool WR rotates, a static frictional force applied by the shaft receiving groove WRc acts on the spool holder 60a and the engaging protrusions 60c abut the partition walls WRd in the circumferential direction, causing the turntable 60 rotates integrally with the wire spool WR. As in 7 shown is a plurality of magnets 60d on the rotation detector 60b attached with a predetermined angular interval. The magnetic sensor 66 is with a Hall IC 66a provided to detect the magnetism of the magnet 60d are configured. As in 3 shown is the magnetic sensor 66 on the outside of the right case 16 arranged. The magnetic sensor 66 is with the control board 34 electrically connected. When the wire spool WR rotates, the magnets rotate 60d the turntable 60 integral with the wire coil WR, and the magnetism generated by the Hall IC 66a is detected changes. The control board 34 is configured to rotate the wire coil WR from the change in magnetism of the magnets 60 by the Hall IC 66a of the magnetic sensor 66 is recorded.

As in 10 shown when the wire spool WR in the take-up mechanism 36 distal ends of the engagement projections can be used 60c ride on the partition walls WRd instead of entering the openings WRe. In such a case, the compression spring 68 compressed and the turntable 60 moves to the right (ie towards the outside of the bobbin holding chamber 20 ). In this state, the bobbin holder bumps 60a not against the WRc shaft notch, the engagement projections 60c are not in the openings WRe, and the distal ends of the engaging protrusions 60c bump against the partition walls WRd. In this state, although the wire coil WR towards the turntable 60 of the right storage mechanism 50 through the shaft component 56 of the left storage mechanism 48 is pressed, there is no great compressive force of the wire coil WR and the turntable 60 applied because the turntable 60 has moved to the right when the compression spring 68 is compressed. Because of this, the wire spool WR rotates relative to the turntable in a simple manner 60 when the feed mechanism 38 pulls the wire from the wire spool WR by passing through the feed motor 72 is driven. Thus, when the feed mechanism 38 pulls the wire from the wire spool WR by passing through the feed motor 72 is driven, the engagement projections 60c into the openings WRe and the coil holder 60a enters the WRc shank, as in 11 shown, whereby it is achieved that the wire coil WR is in its normal holding state.

12 shows a mild steel binding tool 102 a comparative example in which the compression spring 68 is not provided and the turntable 60 not in the left-right direction relative to the inner bearing 62 and the outer camp 64 is slidable (ie, the turntable 60 is in the left-right direction relative to the right case 16 not movable). In this case, the distal ends of the engaging protrusions 60c Riding on the partition walls WRd instead of entering the openings WRe is the case with the structural steel binding tool 102 a significantly high compressive force of the wire coil WR and the turntable 60 applied because the wire coil WR towards the turntable 60 of the right storage mechanism 50 through the shaft component 56 of the left storage mechanism 48 is pressed. Even if the feed mechanism 38 tries to pull the wire W from the wire spool WR by passing through the feed motor 72 is driven in this state, the wire spool WR is not possible in a simple manner relative to the turntable 60 to turn, and the turntable 60 is not able to easily relative to the right case 16 also rotate, and thus a significant large load is placed on the feed motor 72 applied. In contrast, according to the structural steel binding tool 2 of the present embodiment, as in 10 and 11 shown the turntable 60 in the right-left direction relative to the right housing 16 movable, and the compression spring 68 is between the turntable 60 and the right case 16 provided, and thus it can be suppressed that a significantly large load to the feed motor 72 is applied even when the engagement projections 60c ride on the partition walls WRd.

In the above-described embodiment, the configuration in which the pickup mechanism is described is exemplified 36 with the majority of magnets 60d that on the turntable 60 are provided, and the magnetic sensor 66 on the right case 16 is provided for detecting the rotation of the wire coil WR. Different from this configuration, a configuration in which a plurality of magnets are provided directly on the wire coil WR with a predetermined angular interval, and the magnets 60d not on the turntable 60 are intended to be applied. In this case, the rotation of the wire coil WR can also result from a change in the magnetism of the magnets on the wire coil WR by the magnetic sensor 66 is captured, captured. In a case where the rotation of the wire coil WR does not have to be detected, a plurality of magnets cannot be on the wire coil WR or on the turntable 60 be provided, and the magnetic sensor 66 can't on the right case 16 be provided.

In the above-described embodiment, the configuration in which the pickup mechanism is described is exemplified 36 with the majority of magnets 60d that on the turntable 60 are provided, and the magnetic sensor 66 on the right case 16 is provided for detecting the rotation of the wire coil WR. Different to this configuration, as in eg 13 shown, a configuration can be applied in which the pick-up mechanism 36 with a plurality of reflection plates 60e that on the turntable 60 is provided, and an optical sensor 90 is provided on the right housing 16 is provided for detecting the rotation of the wire coil WR. When configuring the in 13 is shown is the optical sensor 90 with a light transmitter 90a configured to emit a detection laser toward the wire coil WR and a light receiver 90b is provided for receiving the laser from the reflection plates 60e is reflected, is configured. Everyone from the light transmitter 90a and the light receiver 90b of the optical sensor 90 is electrical with the control board 34 connected. The majority of reflection plates 60e is on the rotation detector 60b the turntable 60 attached with a predetermined angular interval. The optical sensor 90 is on the outside of the right case 16 appropriate. The right case 16 is with through holes (not shown) through which the light transmitter 90a and the light receiver 90b of the optical sensor 90 to the wire spool WR are provided. According to the configuration that in 13 is shown, the control board 34 the rotation of the wire coil WR from a change in the light (laser) by the light receiver 90b of the optical sensor 90 is captured, capture.

In the above-described embodiment, the configuration is exemplified in which the wire spool WR on the rear portion of the binding tool body 4 is held. However, the wire spool can WR held in any position other than the above. For example, the wire spool WR and the take-up mechanism 36 which is the wire spool WR stops at a position on the lower portion of the binding tool body 4 and on the front of the handle 6 be arranged, for example, a position between the guide mechanism 42 and the battery intake 8th and the feed mechanism 38 and the braking mechanism 40 can above the recording mechanism 36 be arranged.

In the above-described embodiment, the configuration in which the structural steel binding tool is described is exemplified 2 uses a wire spool WR, however, a configuration may be used in which the mild steel binding tool 2 two or more wire coils WR used. For example, the mild steel binding tool 2 with a plurality of recording mechanisms 36 , a plurality of feed mechanisms 38 and a plurality of braking mechanisms 40 be provided which individually hold a plurality of wire coils WR, and wires WR to the guide mechanism 42 feed from the respective wire coils WR.

As described above, in one or more embodiments, the structural steel binding tool 2 the wire coil WR (an example of a coil) having the wire W, the turntable 60 (an example of a wheel) that holds the wire spool WR and is rotatable integrally with the wire spool WR, the right housing 16 (an example of a wheel holder) that the turntable 60 rotates, and the compression spring 68 (an example of an elastic body) on between the turntable 60 and the right case 16 is inserted.

According to the configuration described above, even if the wire spool WR is excessive against the turntable 60 is pressed for some reason, the compression spring suppresses 68 that the excessive pressure force on the wire spool WR and the turntable 60 is applied. Because of this, it can be suppressed that a resistance when turning the wire coil WR and the turntable 60 increases. Furthermore, excessive load can be placed on the feed mechanism 72 which is an actuator that pulls the wire W from the wire coil WR can be suppressed.

In a plurality of embodiments, the wire coil WR is provided with the openings WRe, which are divided by the partition walls WRd. The hub 60 has the engaging protrusions 60c which are configured to enter the openings WRe and abut the partition walls WRd in a direction in which the wire coil WR rotates.

As described above, in the configuration in which the partition walls WRd of the wire coil WR against the engagement protrusions 60c the turntable 60 in the direction in which the wire spool WR rotates, ensure that the wire spool WR and the turntable 60 rotate integrally. However, in the configuration described above, the engaging protrusions can 60c Ride on the partition walls WRd instead of entering the openings WRe when the wire spool WR on the turntable 60 is attached. If the engaging protrusions 60c Riding on the partition walls WRd, the wire coil WR becomes excessive against the turntable 60 pressed compared to the case where the engaging protrusions 60c enter the openings WRe. Because the compression spring 68 between the turntable 60 and the right case 16 is inserted in the configuration described above, the compression spring suppresses 68 that the excessive pressure force on the wire spool WR and the turntable 60 is applied even when the engagement projections 60c ride on the partition walls WRd. Because of this, it can be suppressed that the resistance when turning the wire coil WR and the turntable 60 increases. Furthermore, the excessive load can be applied to the feed motor 72 , which pulls the wire W from the wire coil WR, can be suppressed.

In one or more embodiments, an elastic body is between the turntable 60 and the right case 16 is inserted, the compression spring 68 ,

According to the configuration described above, when the wire spool WR is excessive against the turntable 60 is pressed, the excessive pressure force on the wire spool WR and the turntable 60 be effectively suppressed.

In one or more embodiments, the structural steel binding tool 2 also the left storage mechanism 48 (an example of a push mechanism) configured to push the wire spool WR against the turntable 60 to press.

According to the configuration described above, even if the wire spool WR is excessive against the turntable 60 through the left storage mechanism 48 is pressed, the compression spring is suppressed 68 between the turntable 60 and the right case 16 is inserted that an excessive compressive force on the wire spool WR and the turntable 60 is applied. Because of this, it can be suppressed that the resistance when turning the wire coil WR and the turntable 60 increases. Furthermore, the excessive load can be applied to the feed motor 72 , which pulls the wire W from the wire coil WR, can be suppressed.

In one or more embodiments, the structural steel binding tool 2 a rotation detection mechanism for detecting the rotation of the turntable 60 relative to the right case 16 (such as the combination of the magnets 60d and the magnetic sensor 66 or the combination of the reflection plates 60e and the optical sensor 90 ) is configured.

To detect the rotation of the wire spool WR using such a rotation detection mechanism, the wire spool WR and the turntable must 60 turn safely integrally. However, here is a risk if the wire coil WR is firmly against the turntable 60 to ensure the integral turning of the wire coil WR and the turntable 60 is pressed that the wire spool WR excessively against the turntable 60 could be pressed. According to the configuration described above, even if the wire spool WR is excessive against the turntable 60 is pressed, the compression spring is suppressed 68 between the turntable 68 and the right case 16 is inserted that the excessive compressive force on the wire spool WR and the turntable 60 is applied. Because of this, it can be suppressed that the resistance when turning the wire coil WR and the turntable 60 increases. Furthermore, the excessive load can be applied to the feed motor 72 , which pulls the wire W from the wire coil WR, can be suppressed.

In one or more embodiments, the structural steel binding tool 2 the wire coil WR (an example of a coil) having the wire W, the turntable 60 (an example of a wheel) that holds the wire spool WR and rotates integrally with the wire spool WR, and the right case 16 (an example of a wheel holder) on the turntable 60 holds rotatable. The hub 60 is relative to the right case 16 movable.

According to the configuration described above, even if the wire spool WR is excessive against the turntable 60 is pressed for any reason, the turntable moves 60 relative to the right case 16 , thereby suppressing an excessive pressing force on the wire coil WR and the turntable 60 is applied. It can be suppressed that a resistance when turning the wire coil WR and the turntable 60 increases. Furthermore, excessive load can be placed on the feed motor 72 , which is an actuator and pulls the wire W from the wire spool WR, can be suppressed.

In one or more embodiments, is relative to the right housing 16 the turntable 60 can be moved in a direction along the axis of rotation of the wire coil WR and cannot be moved in a direction perpendicular to the axis of rotation of the wire coil WR.

If an axis of rotation of the turntable 60 is offset from the axis of rotation of the wire spool WR when the turntable 60 relative to the right case 16 moves, the resistance increases when the wire coil WR and the turntable are rotated integrally 60 doing so, and the excessive load becomes the feed motor 72 applied, which pulls the wire W from the wire coil WR. According to the configuration described above, even if the turntable 60 itself relative to the right case 16 moves, the axis of rotation of the turntable 60 not offset from the axis of rotation of the wire spool WR, and thus it can be suppressed that the resistance when the wire spool WR and the turntable are turned integrally 60 increases. Furthermore, excessive load can be placed on the feed motor 72 that pulls the wire W from the wire coil WR can be suppressed.

It is explicitly emphasized that all features disclosed in the description and / or the claims are considered separate and independent from each other for the purpose of the original disclosure as well as for the purpose of restricting the claimed invention regardless of the combinations of features in the embodiments and / or the claims should. It is explicitly stated that all range indications or indications of groups of units disclose any possible intermediate value or subset of units for the purpose of the original disclosure as well as for the purpose of restricting the claimed invention, in particular also as a limit of a range specification.

Claims (7)

Structural steel binding tool (2), with a coil (WR), which has a wire (W), a wheel (60) which holds the spool (WR) and is rotatable integrally with the spool (WR), a wheel holder (16) which rotatably holds the wheel (60), and an elastic body (68) inserted between the wheel (60) and the wheel holder (16). Structural steel binding tool (2) after Claim 1 , wherein the coil (WR) is provided with an opening (WRe) divided by a partition wall (WRd) and the wheel (60) has an engaging protrusion (60c) configured to be inserted into the opening (WRe ) to enter, and to abut the partition wall (WRd) in a direction in which the coil (WR) rotates. Structural steel binding tool (2) after Claim 1 or 2 , in which the elastic body (68) is a compression spring (68). Structural steel binding tool (2) according to one of the Claims 1 to 3 further comprising a push mechanism (48) configured to push the spool (WR) against the wheel (60). Structural steel binding tool (2) according to one of the Claims 1 to 4 further comprising a rotation detection mechanism (60d, 66; 60e, 90) configured to detect rotation of the wheel (60) relative to the tool holder (16). Structural steel binding tool (2), with a coil (WR), which has a wire (W), a wheel (60) holding the spool (WR) and rotatable integrally with the spool (WR), and a wheel holder (16) which rotatably holds the wheel (60), in which the wheel (60) is movable relative to the wheel holder (16). Structural steel binding tool (2) after Claim 6 , in which the wheel (60) is movable relative to the wheel holder (16) in a direction along an axis of rotation of the coil (WR) and is not movable in a direction perpendicular to the axis of rotation of the coil (WR).

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