KR100980088B1 - Electric apparatus for riveting - Google Patents

Abstract

The riveting power tool of the present invention is connected to the motor can be rotated forward and backward, the screw thread or screw groove on the side, the rear rotating portion having a coupling portion formed so that the rivet axis direction of the screw travel direction; A front rotation part installed in the housing and installed to transmit rotational force to the blind rivet; The rear end has a screw coupling portion that is screwed with the coupling portion, the front rotary portion is installed to be rotatable with the front rotary portion or slidable in the rivet axial direction, depending on whether the front rotary portion can be rotated, and the front end to hold the rivet core of the blind rivet A moving core having a deep chuck; Installed in the housing so as to alternate between the first position and the second position, the first position is spaced apart from the front rotation portion to enable the rotation of the front rotation portion, in the second position is coupled with the front rotation portion of the front rotation portion Having a clutch portion to prevent rotation;

It eliminates the hassle of alternating riveting tools or riveting machines separate from the drilling machine, reduces working time, and enables automatic ejection of rivet seams to increase work convenience and reduce working time. .

Description

Power tool for riveting {ELECTRIC APPARATUS FOR RIVETING}

The present invention relates to a power tool for riveting. Particularly, the present invention inserts and fixes the blind rivets to the nozzle of the power tool, and then drills the fastening holes in two or more plates to be joined by using the drill blades of the blind rivets, and pulls the blind rivet cores with the drawing chuck inside the power tool. It relates to a power tool for riveting that allows the expansion cylinder to expand and join the plates.

Typically, rivets are mechanical elements for fastening two or more materials together, which are made by drilling holes in the plate to be fastened, inserting the rivets, and then forming a locking jaw or head with a hammer or other mechanical device. You will complete the rivet join. Since the riveting work to perform such riveting is usually done by hand, the connection process is complicated, and the failure rate is greatly dependent on the skill of the operator.

Therefore, in recent years, various types of rivets have been developed to enable simple and efficient riveting operations. A representative example of the developed rivets is blind rivets.

Blind rivets generally consist of a rivet shim having a head, a rivet body and a cutting groove, and an expansion cylindrical body coupled to the rivet shim and consisting of an expansion cylinder and a flange. To fasten the blind rivets, drill a fastening hole in the two or more plates, and insert the head of the blind rivet into the fastening hole so that the flange part touches the plate, and then use a separate tool to insert the rivet core. Pull to extend the head side end of the expansion cylinder. At this time, the rivet body is separated from the cutting groove in the rivet shim at the final stage of the expansion cylinder is expanded and the rivet coupling is completed.

However, in such a riveting operation, a tool for pulling a rivet seam is used separately from a tool for drilling, and therefore, a separate operation of drilling a fastening hole in the butted plate must be performed before the riveting operation.

Thus, in the case of using blind rivets, the riveting operation is easier than conventional manual riveting, but there is still the inconvenience of still having to manually drill the fastening holes.

The present invention is to solve such a conventional problem, to provide a riveting power tool that can be carried out in a single tool by drilling and riveting before riveting using a blind rivet on the plate to be joined The purpose.

In addition, the present invention provides a riveting power tool that can be continuously performed to remove the remaining rivet seam of the blind rivet after the drilling and riveting operation with a single tool using a blind rivet For the purpose of

The riveting power tool according to the present invention for achieving the above object, the housing; A motor rotating in a forward or reverse direction installed in the housing; A rear rotation part connected to the motor and capable of reverse rotation, having a screw thread or a screw groove formed on a part of the side thereof, and having a coupling part formed such that a rivet axis direction is a screw travel direction; A front rotation part installed in the housing and installed to transmit rotational force to the blind rivet; The rear end has a screw coupling portion that is screwed with the coupling portion, the front rotary portion is installed to be rotatable with the front rotary portion or slidable in the rivet axial direction, depending on whether the front rotary portion can be rotated, and the front end to hold the rivet core of the blind rivet A moving core having a deep chuck; Installed in the housing between the first position and the second position so as to be spaced apart from the front rotation part in the first position to enable the rotation of the front rotation part, in the second position is combined with the front rotation part in the front rotation part To prevent the rotation of the clutch portion; characterized in that having.

In the present invention, when the motor rotates in reverse, a one-way bearing supporting the front rotation part may be further provided to prevent rotation of the front rotation part.

In the present invention, the moving core is formed with a cylindrical rear cap which is formed to form a narrow section at the front end to prevent the core chuck from moving forward, and is fixedly coupled to the rear end of the front cap and has a core rear end having a screw coupling part. The core chuck may be installed in the shear cap with a plurality of pressing pieces that exert a force acting toward the axis center. In addition, the moving core may be further provided with a core spring that can be compressed by an external force while pushing the core chuck in a narrow section of the shear cap between the core rear end and the core chuck.

In the present invention, the front rotating part is formed in a cylindrical shape as a whole, and in some side wall sections, there is a slit forming part in which a slit is formed in the axial direction of the rivet seam, and a protruding tip protruding outward to be inserted into the slit is formed in the moving core part, so that the motor rotates forward. When the clutch part is in the first position, the moving core part transmits the rotational force of the motor to the front rotation part, and when the clutch part is in the second position, the slit and the protruding tip serve as the moving guides so that the moving core part slides forward. have.

In the present invention, the front end of the front rotating portion may be a rivet core can be in and out, the rear end is protruding sharply protruding tip formed to reduce the pressure to hold the rivet core crushing piece chuck.

In the present invention, when the front end of the front portion has a shear tip formed with a hole for entering the rivet seam, the shear tip hole is a size corresponding to the cross-sectional size and shape of the rivet seam so that the shear tip can transmit the rotational force to the rivet seam It is preferably made in the form of and to be able to replace the shear tip according to the type of rivet.

In the present invention, when the drilling operation for the blind rivet is completed by the drill portion of the rivet end in the state in which the rivet is mounted by the forward rotation of the motor is provided with a reverse conversion switch for generating a signal for changing the rotation of the motor from the forward direction to the reverse direction Can be. In addition, a reverse switch may be provided to generate a signal for changing the rotation of the motor from the reverse direction to the forward direction after the riveting operation by drawing for the blind rivet is finished and the rivet seam is broken.

In the present invention, the clutch portion has a fixed portion fixed to a certain position in the housing and a moving portion movably coupled to a predetermined range between the first position and the second position in the fixed portion, the moving portion is the moving core at the foremost end. When present, the front rotation part is engaged with the front rotation part so that the front rotation part is rotatable, and when the moving core part is at the rear end, the front rotation part is engaged with the front rotation part so that the front rotation part is in a second position that cannot be rotated. Can be.

For example, the front rotating part is generally cylindrical, and in some side wall sections, the slit forming part is formed in the slit in the axial direction of the rivet seam, and the moving core part is formed at the rear end when the protruding tip is formed to protrude outwardly to be inserted into the slit. When moving from the front end to the protruding tip is pushed to move the moving portion to the first position, and when the moving core is moved from the front end to the last end can be made to push the moving portion to the second position.

Alternatively, each forward and reverse switch senses the position of the moving core in a state in which the forward and reverse switch for the motor rotation direction is provided for automation, thereby changing the position of the moving part of the clutch, and at the same time, changing the rotation direction of the motor. The work of drawing, drawing and removing rivet seams may be carried out continuously.

Therefore, according to the present invention, when blind riveting is performed to join two or more thin sheets, non-ferrous metal sheets, or resin-type plates, which are difficult to be welded, the plate is drilled by a separate drilling machine in the operation, and then blind rivets are inserted. It saves you time and eliminates the hassle of using separate hand riveting tools or different types of riveting machines.

In addition, after the blind riveting operation is pulled by the deep chuck, it is possible to automatically discharge the remaining rivet seam has the advantage of increasing the convenience of the work, reducing the working time.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 and 2 discloses a riveting power tool configuration forming an embodiment of the present invention. The power tool for riveting of the embodiment is made in the shape of a pistol having a main body 100 and a handle 10 as in a conventional electric drill. In the main body portion 100 having a pistol shape, most of the components are installed in a common axial direction (the longitudinal direction of the barrel), in particular in the barrel portion, and the motor 110 and the transmission 120 are located behind the barrel portion, and the handle portion An adjustment means such as an adjustment switch 15 is provided at 10.

In more detail, the motor 110 that rotates in the forward or reverse direction within the pistol-shaped housing 40 is disposed at the rear of the main body portion 100 with respect to the barrel portion. One gear 125 of the transmission 120 is coupled to the motor shaft 111 in front of the motor 110, and the transmission shaft 121 connected to the other gear 123 of the transmission has a cylindrical rear rotating portion ( 140) is fixed to the rear end.

The cylindrical rear rotating portion has a screw groove on the inner wall surface of the cylinder (cylinder), and the outer wall surface is rotatably supported by the bearing in the housing 40.

The front rotation part 150 has a cylindrical shape or a cap shape in which the front part is partially closed, and may be divided into a rear end part 151 and a front end part 155. In some sections of the sidewall between the front end 155 and the rear end 151, the slit 159 has a slit forming portion formed in the rivet axial direction. The front end of the front end 155 is partially closed by the front end tip 157. The shear tip 157 has holes in the shape and size corresponding to the rivet shim 26 so that the center of the blind rivet 26 passes therethrough. The shear tip 157 can be used with various types and replacements to have corresponding holes depending on the size and cross-sectional shape of the rivet shim. That is, the shear tip is coupled to the front end of the front end 155 and can be easily replaced. As the size of the rivet shim of the blind rivet increases, the shear tip having the small hole is removed from the front end of the front end, and the front end having the big hole Tip 157 is inserted into the front end of the screw threaded form or socket coupled form. The rear end of the front end tip 157 is formed so that the periphery of the hole protrudes backward sharply at an obtuse angle.

The front rotation part 150 is rotatably supported by support bearings 171 and 175 fixed to the housing 40 at the periphery. Some bearings supporting the front rotation part 150 are constituted by one way bearings 173 such as clutch bearings, so that the front rotation part 150 can rotate in the forward direction but not rotate in the reverse direction. The one-way bearing 173 is usually installed between the housing and the front rotational part and eventually formed so that the housing 40 supports the front rotational part 150, but the one-way bearing 173 must necessarily be directly coupled to the housing 40. There is no.

The moving core 160 is installed in the inner space of the cylindrical front rotation part 150 to move in the rivet core direction. The moving core 160 includes a core chuck 167 and a core spring 163 installed in the core rear end 161, the front cap 165, and the front cap 165. Core rear end 161 is the main body 161d, the connecting portion 161a which is located in front of the main body and coupled with the front cap 165, protrudes outward from the main body and is inserted into the slit 159 of the slit forming portion of the front rotary part 150 Protruding tip 165c, which is positioned behind the main body in a cylindrical shape, the thread is formed on the surface is provided with a screw engaging portion (161c) is screwed into the inner wall screw groove of the cylindrical rear rotating portion (140).

The shear cap 165 is in the form of a cylinder, preferably in the form of a circular cylinder, through which the shim 26 of the blind rivet passes through. At the foremost end where the rivet shim 26 is drawn in, the inner diameter of the rivet core 26 is extended, and the side wall has a tapered section 165a in which the thickness is thinned. Instead of providing a tapered section, it is also possible to form a short section with a narrow cylinder inner diameter in the form of a neck simply at the foremost end of the shear cap 165.

The rear end portion of the front end cap 165 is fixed by pressing the connecting portion 161a of the rear end portion 161. The fixing may consist of a simple socket-type coupling but may also form gear toothed grooves and protrusions that engage each other on the coupling surface to facilitate the fixing.

Referring to FIG. 3, the core chuck 167 is provided with a plurality of compression pieces 167a in front of the core chuck body 167b so that the rivet shims 26 are inserted or removed when the compression pieces are opened to the outside, and the compression pieces 167a are provided. ) Is made to firmly fix the rivet shim (26) when it is inward. The pressing piece is formed to have a tendency to squeeze by elasticity in the usual time, and the pressing piece 167a is fitted into the tapered section 165a of the front end cap when the moving core 160 is pushed forward in the front end cap 165. Losing takes form. A deep spring 163 in the form of a compressed coil spring is installed between the deep chuck 167 and the connecting portion 161a so that the deep chuck main body 167b and the pressing piece 167a are brought into close contact with the front of the shear cap 165. Beauty works. However, at the front end of the front end cap, a part of the front end of the front end of the front end tip 157, which is sharply protruded, slightly pushes the compression piece outwards like a wedge so that the rivet seam enters between the compression pieces of the core chuck and is fixed. To facilitate. When the rivet shim is drawn in, the crimping piece in contact with the rivet shim should have a gentle inclination to facilitate receiving the rivet shim. In this state, the press piece simply grips the rivet shim at a pressure that does not slip.

When the rivet shim 26 is pulled back by the force of the motor in the drawing step for riveting, the entire moving core 160 is spaced apart from the shear tip so that the core chuck compression piece 167a is spread out of the shear tip 157. Since the force is not applied, the inserted rivet shim can be fixed more firmly.

On the other hand, the front end of the front rotating part 150, the rivet core 26 can enter and exit and the rear end is protruding sharply so that the pressing tip 157 is formed so as to reduce the pressure to hold the rivet shim pressing piece (167a) is installed Therefore, during the forward rotation, the crimping piece simply grabs the rivet seam, and since the hole of the shear tip is selected to correspond to the size and shape of the rivet seam, the shear tip mainly serves to transmit the rotational force to the rivet seam.

However, in the drawing step, since the crimping piece must hold the rivet seam firmly, if the cross-section of the rivet seam is polygonal, the contact portion with the rivet seam has a polygonal cross-section corresponding to the cross-section of the rivet seam when the plurality of crimping pieces 167a also hold the rivet seam. It is preferable that it is made so that.

The clutch unit 130 includes a fixing unit 131 fixed to a predetermined position in the housing 40 and a moving unit 133 operatively coupled to a fixed range in a range between the first and second positions. It is made. In order to move the moving part 133 between the first position and the second position, the fixing part 131 has a ball installation part provided with a ball 1315 to protrude convexly inward from the surface of the fixing part. At this time, the ball installation portion in the compression coil spring (1313) in the groove 1311 of a circular constant diameter formed at one position of the fixing portion 131, but the ball (1315) almost the same as the diameter of the groove (1311) on the spring (1313) To adjust the length and elasticity of the springs 1313 to allow the balls 1315 to protrude out of the grooves, and above the balls 1315 a diameter smaller than the diameter of the balls to prevent the balls from leaving the grooves 1311. The branch can be formed by installing the ring 1317 at the inlet of the groove. The moving part 133 is installed on the fixing part inner surface to slide the fixing part inner surface in the rivet core axial direction. Guide means may be installed on the surfaces facing each other to move only in the direction of the rivet core axis using grooves and ribs. Two seating grooves 1331 and 1333 and a connecting portion 1335 between these two seating grooves may be formed on a surface of the moving part 133 which serves as the guide means or separately from the guide means. have.

The two seating grooves 1331 and 1333 are spaced a certain distance in the direction of the rivet axis, and each seating groove has a size corresponding to the size of the ball protruding from the surface ball mounting portion of the fixing part. When in the groove, the moving part and the fixing part try to keep the position stable with each other, unless an external shock or force is applied.

However, when an external force or impact is applied to the moving part 133, the moving part 133 moves, and thus, the ball 1315 moves from one seating groove to another seating seat. Since the ball is to be protruded as much as possible by the spring 1313 of the ball mounting portion, the groove between the seating groove and the seating groove is made of a shallower than the seating groove, or in the transition section that does not have a groove at all, the moving part 133 is fixed part 131 ), It is not coupled stably, and it moves until the ball is seated in one of the two mounting grooves.

The shear rib 1334 in front of the moving part 131 has a gear forming part 1339 at the rear side, and a flange part is also present at the rear end of the front cap 165 of the front rotating part 150 so that the gear is located at the front side of the flange part. There is another gear forming portion 1551 corresponding to the forming portion 1339. Therefore, in the first position where the moving part moves relatively forward, the gear forming parts 1339 and 1551 are not engaged with each other, so that the front rotation part 150 transmits the rotational force of the motor 110 through the moving core part 160. When receiving, the front rotating part 150 rotates together with the moving core 160, but the gear forming parts are coupled to each other in the second position where the moving part 133 moves relatively backwards, so that the clutch part 130 is the front rotating part ( The rotation of 150 is prevented.

On the other hand, the front and rear muzzle portion of the pistol-shaped housing 40, as shown in Figure 4 can be installed to serve as a sensor, a forward and reverse switch 180 to automatically change the rotational direction of the motor. For example, the forward / backward switch may include a contact end 181, a spring 183, a moving contact 185a, a locking step 185b, a moving shaft 185, a fixed contact 187, an inner case 189b, and an outer case 189a. ) May be provided. When the drilling operation is completed using the blind rivet 20, the riveting power tool itself approaches the plate to be coupled, and when the contact end 181 protruding forward reaches the plate 30, the contact end 181 is In spite of the pressure of the spring 183, the movement contact 185a connected to the contact end 181 and the movement shaft 185 moves rearward together to touch the fixed contact 187 to conduct current. That is, the forward and reverse switch is turned on.

When a current flows through the connection wire, not shown, a current signal is inputted to an unshown controller that controls the motor 110, and the rotation direction of the motor 110 is switched. When the riveting power tool completes the riveting through rivet seam drawing and is spaced apart from the plate 30 according to the rivet seam break, the spring 183 is restored to its original shape and the locking jaw 185b of the movable shaft 185 is removed. Push toward the outer case 189a side to move both the movement contact 185a and the contact end 181 fixed to the movement shaft 185 forward, and the fixed contact 187 of the movement contact 185a and the inner case 189b. ) Are also spaced apart to switch off.

Normally, however, such a forward-switching switch will be in the form of turning on the motor once the pulse signal is electronically acted on the motor regulator once the ON state is turned on regardless of the switch contact. In this case, the switch of the forward / backward switching is meaningful in that the switch-off provides a state in which the pulse signal is generated at the next switch-on state through a component such as a capacitor on the circuit.

On the other hand, in the present embodiment, there is one more forward and reverse switch 190 that is operated when the clutch unit 130 is switched to the second position. This forward and reverse switch 190 also has a configuration substantially the same as the forward and reverse switch 180 provided at the front end of the housing 40. When the protruding tip 161b of the moving core part 160 moves backward by the reverse rotation of the motor 110, the rear part 1336 of the moving part 133 of the clutch part pushes backward, and the moving part 133 is in the second position. While moving to press the contact end of the forward and reverse switch 190 is rearward. The switch is turned on at the contact of the forward / reverse switch. The pulse signal is transmitted to the controller of the motor 110. The motor 110 is in the forward rotation state in the reverse rotation again.

Hereinafter, the process of performing the riveting operation using the blind rivet 20 in the embodiment of the present invention.

First, the operator inserts the rivet shim 26 of the blind rivet 20 into the core chuck pressing piece 167a of the power tool for riveting through the shear tip 157. Originally, the crimping piece tends to retract toward the center due to elasticity, so that the rivet shim is not easily sandwiched between the crimping pieces. However, since the core spring 163 pushes the core chuck 167 to the front end of the front end cap 165, that is, the inner diameter of the tapered section 165a, the crimping piece is influenced by the rear end of the front end tip 157. The outwardly open state allows the rivet shim to be sandwiched between the pressing pieces relatively easily.

When the rivet core is fitted to the core chuck, the operator puts the rivet core, and the core chuck is pushed forward by the core spring 163, and the rivet core is fixed to the core chuck between the pressing pieces at the front end of the shear cap. At this time, since the protruding portion of the rear end of the front end tip 157 at an obtuse angle touches the pressing piece 167a, the rivet core 26 is not firmly fixed to the pressing piece 167a of the core chuck 167. Riveting the force in the axial direction of the rivet can be seen that the axial sliding to some extent fixed. However, when it is in the forward rotation, the rivet shim 26 receives a rotational force from the shear tip 157 having a hole corresponding to the rivet shim, so that the rivet shim 26 is drilled into the plate so that it is not necessary to be firmly fixed to the core chuck 167. do. However, it is preferable that the plurality of compression pieces 167a also grip the rivet shim while forming the shape of the rivet shim 26 to prevent the rivet shim from turning out.

Next, when the control switch 15 of the handle portion 10 is rotated to rotate the motor 110 in the forward direction, the rotational force of the motor is transmitted to the rear rotating portion 140 through the transmission 120.

The rear rotating part 140 rotates in the forward direction, and the screwing part 161c of the moving core 160, which is screwed with the screw groove of the inner side surface of the cylindrical side wall of the rear rotating part 140, is also moved to the foremost position. The rivet seam of the movement is impossible, and tries to rotate with the rear rotating part 140.

The screw coupling portion 161c is connected to the main body 161d of the rear end portion 161 of the moving core, and the protruding tip 161b protruding outward of the main body is fitted to the slit forming portion slit 159 of the front rotation part 150. There is also a front rotation part 150 also rotates together. Instead of using the slit 159 and the protruding tip 161b, if the portions corresponding to each other of the front rotation part 150 and the moving core 160 are replaced with cylindrical and cylindrical instead of cylindrical and cylindrical, they can also slide in the rivet axial direction. And it becomes possible to be configured to transmit the rotational force during rotation.

Although there is a difficulty in processing, if the core chuck 167 portion, for example, the core chuck body 167b and the core chuck counterpart in the shear cap 165 are formed in a rectangular shape, the possibility of slipping between the core chuck and the shear cap during rotation may be more completely eliminated. Can be.

Fig. 6 is a longitudinal sectional view showing one example of the blind rivet used through the present invention and a cross sectional view of the rivet core portion.

The rivet consists of a drill blade 21, a rivet core, an expansion cylinder 27, and the rivet core is divided into a head 23 and a rivet core 26 around a cutting groove 25, which is a weak part cut at the time of drawing. Lose. The expansion cylindrical portion 27 serves as a stopper when the rivet hole is drilled at the rear end, and may be divided into a flange portion 27a and an expansion cylindrical body forming the head of the rivet.

The rivet shim 26 fitted to the core chuck 167 of the moving core 160 is also square, and the crimping piece holding the rivet shim also fixes the rivet shim in a shape that fits the square, so that the rivet shim 26 at the time of rotation eventually becomes a motor. The rotational force of 110 is transmitted.

Since the front end of the blind rivet 20 forms a sharp drill blade 21 made of a strong material, it is possible to easily drill a plurality of plate members 30 overlapped to be joined.

As the drilling operation is performed, the plate 23 gradually passes from the head 23 of the blind rivet 20, and finally the outer extension formed at the rear end of the expansion cylindrical portion 27, that is, the flange portion 27a, touches the plate 30. Cotton drilling is completed. From this point, it is necessary to pull back the rivet shim (26).

Power for pulling back the rivet shim 26 for drawing operations may also be supplied by the motor 110. First, the forward and reverse changeover switch 180 in front of the muzzle portion of the present embodiment in the shape of a pistol has a contact end 181 and a moving contact 185a rearward when the rear flange 27a of the expansion cylinder touches the plate 30. While moving, the movable contact may be in contact with the fixed contact 187 to flow a current signal. That is, the contact of the forward and reverse switch 180 is formed to be on. To this end, the forward and reverse changeover switch 180 may have an adjustment screw (not shown) for adjusting the projecting degree of the protruding contact end 181. An exemplary configuration of a forward and reverse switch has already been made in the embodiment structure description through FIGS. 1 and 2.

When a pulse signal is input from the forward / reverse switch to the regulating circuit of the motor according to the forward / reverse switch on, the rotation direction of the motor 110 is reversed by the switching means in the circuit. The rear rotating part 140 also rotates in the reverse direction.

However, since the rotation direction is controlled by the one-way bearing 173, the front rotation part 150 cannot rotate in the reverse direction. Therefore, the rotation stops. The front rotating part 150 and the rear rotating part 140 are not physically in contact with each other, or are slidably coupled to each other so that the stop state of the front rotating part does not affect the rotation of the rear rotating part.

At the same time, the screw engaging portion 161c of the movable core 160 screwed with the rear rotating portion is slidably moved backward in the axial direction according to the reverse rotation of the rear rotating portion. Since the protruding tip 161b can be guided and moved by the slit 159 of the slit forming section, the moving core part slides backward in its inner space without obstruction of the front rotating part while the front rotating part does not move.

This movement also corresponds to the core chuck 167 which firmly holds the rivet shim 26 as the moving core retreats, and the head 23, which is the front end of the rivet core, is the drill blade 21 portion or the expansion cylinder portion of the rivet front end. (27) Since the core chuck 167 is fixedly coupled to the front end portion, the tension force acts on the rivet core to move backwards, and the front end portion of the drill blade portion and the expansion cylinder portion with the flange portion 27a of the expansion cylinder portion intact. Will pull. Since the expansion cylinder portion 27 is formed of a relatively soft metal, the expansion cylinder portion 27 is deformed by the tensile force and is expanded outward to form the rivet head opposite to the flange portion 27a.

If the tensile force continues to act, the newly formed rivet head cannot pass through the perforation hole of the plate, so the tensile force on the rivet seam increases, so that the relatively weak portion of the cutting groove breaks. At this time, the riveting work is completed, the rivet is formed to join the plate. However, the rivet core is still in the core chuck 167 of the moving core 160 of the riveting power tool of this embodiment.

When the reverse rotation of the motor continues, the moving core portion 160 continues to move backwards, and in the process, the protruding tip 161b of the moving core contacts the moving portion rear rib 1336 of the clutch unit 130 and the rear rib ( 1336) to move backward. When the moving part moves rearward, the gear forming part 1339 formed on the front rib 1334 of the moving part is engaged with the star forming part 1551 of the front rotating part 150.

At the same time, the moving part rear ribs turn the other forward and reverse switch 190 on. In the on state, the forward and reverse changeover switch 190 transmits a pulse signal to a control circuit that controls the rotation of the motor to change the rotation direction of the motor in the forward direction. The rear rotating unit 140 also rotates in the forward direction.

At this time, since the moving part can move in a certain range in the rivet axis direction in relation to the fixing part, but the rotational movement is impossible, the front rotating part 150 coupled to the star forming part 1339 of the moving part also becomes incapable of rotating. As opposed to when the reverse rotation of the reverse rotation of the rotating portion in the forward direction, the screw engaging portion (161c) of the moving core is to slide forward. When the moving core moves to the foremost front, the moving core is further blocked by the front end tip 157 of the front rotating part 150. At this time, the crimped piece of the deep core chuck of the moving core part is formed by a portion projecting at an obtuse angle to the rear of the shear tip, and the rivet core is in a state capable of moving in the axial direction. Therefore, the moving core is blocked by the inertia of the moving core moving forward in the front rotation part, but the rivet core continues to move so that most of it is exposed to the front side of the shear tip or can be completely discharged from the power tool.

An auxiliary alarm device is provided together with the forward / reverse switch to generate a flash signal or a voice signal so that the user can clearly recognize when the forward / reverse switch switches 180 and 190 are operated, that is, when the rotation direction of the motor is changed by the forward / reverse switch. You can install more.

On the other hand, although not clearly shown, a power source is required for the rotation of the motor, and the control switch 15 capable of applying the power to the motor or switching the rotation direction is required. The control switch 15 is conveniently installed in the handle portion 10 in the housing 40 in the form of a pistol. The power switch or the control switch 15 of the handle portion may be a simple on / off function in consideration of the forward / reverse switch, but the forward direction in consideration of the possibility of the absence or failure of the forward / reverse switch or the manual adjustment by special needs It is desirable to have a reverse adjustment function.

In the above embodiment, the one-way bearing for supporting the front rotation part to prevent the rotation of the front rotation part in the reverse rotation of the motor plays a key role, but the one-way bearing in the present invention can also play a role in the clutch part This is not indispensable. In this case, however, a switching means similar to a forward / reverse switch for shifting the position of the moving part in the clutch part in a timely manner is required, or at that time, the user needs a means for moving the moving part of the clutch part according to a function by an operation. The configuration can be complicated.

Although not shown, the controller 110 may adjust the forward and reverse rotations of the motor 110, and may include a controller such as a controller formed on a PCB for controlling interaction with the forward / reverse switch 180 or the control switch 15. Control circuit configuration in which the forward and reverse rotation of the motor is switched by the forward and reverse switching switch can be made in a variety of ways simply in the field of circuitry, and since it is not an essential part of the present invention, an example of a specific circuit configuration will be omitted.

In addition, elements such as the motor 11 is fixedly installed in the housing by a separate bracket or other fixing device. Hereinafter, as in the case of the motor 11, specific elements of the fixing structure for the components that need to be fixed in the housing 40 are required. Description is omitted since it is a general technical scope.

1 and 2 are front cross-sectional views respectively illustrating a drilling step and a drawing completion step of the riveting power tool according to an embodiment of the present invention;

Figure 3 is a partial front view of the moving core showing the form in which the rivet core is inserted and fixed to the moving core in an embodiment of the present invention,

4 is a partial front view showing a forward and reverse switch in an embodiment of the present invention;

5 is a partial side view of the clutch unit according to the embodiment of the present invention seen from the rear;

6 is a longitudinal sectional view and a cross sectional view showing the configuration of one example of the blind rivet according to the present invention.

-Explanation of symbols for the main parts of the drawings

10: handle 15: control switch

20: blind rivet 21: drill blade

23: head 25: cutting groove

27: expansion cylinder part 27a: flange part

26: rivet core 40: housing

110: motor 130: clutch portion

131: fixing portion 1311: groove

1313: spring 1315: ball

1317: ring 133: moving part

1311,1313: settling groove 1334: front rib

1336: rear rib 1235: connection

1338: shear jaw 1339: gear forming portion

140: rear rotating part 150: front rotating part

151: rear end 155: front end

157: shear tip 159: slit

1551: gear forming portion 160: moving core portion

161: rear end 161a: connection portion

161b: projecting tip 161c: screw connection

161 d: main body 163: core spring

165: shear cap 165a: taper section

167: deep chuck 167a: crimping piece

167b: main body 171,175,177,179: support bearing

173: one-way bearing 180,190: reverse switch

181: contact end 183: spring

185a: Moving contact 185b: Jamming jaw

185: moving shaft 187: fixed contact

Claims (8)

delete housing; A motor installed in the rear portion of the housing and rotatable in a forward or reverse direction; It is installed in the housing in front of the motor, connected to the motor to be rotated in the forward or reverse direction, but fixed in the forward and backward direction, the thread or screw groove on the side, so that the rivet axis direction is the screw travel direction A rear rotating part having a coupling part formed; A moving core part installed at the front of the rear rotating part in the housing and having a screw coupling part at a rear end thereof, the screw coupling part being screwed while varying the coupling part and the coupling part, and having a core chuck at the front end having a rivet core of a blind rivet; Rotating with the moving core around the moving core in the housing, and coupled to be fixed in the front, rear direction, when the rotation is possible, receives the rotational force of the motor from the moving core and rotates with the moving core, the rotation When this is not possible, the front rotation part serving as a slide guide to prevent the moving core portion to rotate, the moving core portion to move in the front, rear direction while the coupling section of the screw coupling portion is changed by the rotational force of the motor; The housing is installed to alternate between a first position and a second position, and the first position is spaced apart from the front rotation part to enable rotation of the front rotation part, and in the second position, the front rotation part is coupled to the front part. Has a clutch portion to disable the rotation of the rotating portion, The moving core has a cylindrical front cap formed to form a narrow section at the front end to prevent the core chuck from being separated from the front and fixed to the rear end of the front cap, and has a core rear end having the screw coupling portion, The core chuck is installed in the shear cap with a plurality of pressing pieces that the force acting toward the center of the axis, A riveting power tool between the deep end and the deep chuck is provided with a deep spring which acts to push the deep chuck to the narrow section of the shear cap and can be compressed by an external force. The method of claim 2, The front rotating part is formed in a cylindrical shape as a whole, and in some side wall sections there are slit forming parts formed with slits in the axial direction of the rivet seam, The moving core portion is provided with a protruding tip protruding outwardly to be inserted into the slit so that the moving core portion transmits the rotational force of the motor to the front rotating portion when the clutch portion is in the first position during forward rotation of the motor. And the slit and the protruding tip serve as a movement guide when the clutch portion is in the second position so that the movement core portion slides forward. The method of claim 2, The front end of the front rotating portion is provided with a replaceable shear tip hole is formed so that the rivet core can enter and exit, The hole is a riveting power tool, characterized in that the shear tip is made of a size and shape corresponding to the cross-sectional size and shape of the rivet shim so as to transmit a rotational force to the rivet shim. The method of claim 2, The clutch part has a fixed part fixed to a predetermined position in the housing and a moving part movably coupled to a certain range between the first position and the second position in the fixed part, The moving part is located in a first position where the front rotating part is disengaged from the front rotating part when the moving core part is at the foremost end, and the front rotating part is engaged with the front rotating part when the moving core part is at the rear end. Power tool for riveting, characterized in that the front rotary part is in a second position where it is impossible to rotate. The method of claim 5, The front rotating part is formed in a cylindrical shape as a whole, and a part of the side wall has a slit forming part in which a slit is formed in the axial direction of the rivet seam, and the moving core part has a protruding tip projecting outward to be inserted into the slit. When the moving core moves from the rear end to the foremost end, the protruding tip pushes the moving part so as to be in the first position. When the moving core moves from the front end to the rear end, the protruding tip pushes the moving part to the second position. Power tool for riveting, characterized in that configured to switch to the position. The method of claim 5, A forward and reverse switch for generating a signal for changing the rotation of the motor from the forward direction to the reverse direction when the drilling operation for the blind rivet is completed; When the riveting operation by drawing for the blind rivet is finished, there is provided a reverse switch for generating a signal for changing the rotation of the motor from the reverse direction to the forward direction, And the forward and reverse switch for generating a signal for changing the rotation of the motor from the reverse direction to the forward direction is operated while the moving part is switched from the first position to the second position. The method of claim 2, Riveting power tool, characterized in that when the reverse rotation of the motor further comprises a one-way bearing for supporting the front rotation to prevent the rotation of the front rotation.

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