KR101071404B1 - A riveting electric tool - Google Patents

Abstract

The present invention relates to a hydraulic hydraulic riveting power tool for a drill, which forms a drill portion for drilling a construction hole in a work object on one side of a handle, and integrally forms a rivet portion operated by a hydraulic pump on the opposite side of the drill portion. It is characterized by.

The present invention forms a drill portion on one side of the handle, by forming a rivet portion on the opposite side of the drill, can be used easily and simply alternately drill and riveting work is possible to proceed quickly, there is an effect to shorten the construction period In addition, the present invention can be configured by the hydraulic drive method of the structure of the riveting device, it is possible to easily configure the internal structure, reduce the number of parts used to reduce the production cost, and can reduce the weight of the power tool It has a convenient effect.

Drills, Rivets, Power Tools, Hydraulic

Description

Hydraulic riveting electric tool for drills {A riveting electric tool}

The present invention relates to a riveting power tool for use in riveting a combination of various plates, such as two or more steel sheet, synthetic resin board, wooden board, more specifically, to form a drill portion for drilling the work hole in the plate on one side In addition, the present invention relates to a drill combined hydraulic riveting power tool configured to form a riveting part for riveting the riveting pin on the opposite side of the drill part.

Conventionally, as described in Korean Patent Publication No. 98-702261 (published on July 7, 1998), a conventional riveting apparatus is known. The worm is rotated while the torque is decelerated through a plurality of gears, and the torque transmitted to the worm rotates the cog wheel of the crank rod-type connecting rod to pull the crank rod-type connecting rod. As the jaw piston is pulled out, the riveting pin is inserted into the inner tip of the jaw piston.

In this state, the driving pinion that transmits power to the worm and the rotating cylinders that rotate independently of each other rotate to rotate the riveting pins that are bitten by the jaws, so that the riveting pins are inserted into the plate while drilling the plate to be riveted. After pulling the trigger switch hard again, the length of the pulling rod of the crank rod-type connecting rod is lengthened so that the pin part of the riveting pin is cut and riveted.

However, such a conventional riveting device requires a very large force when pulling the riveting pin so that the pin portion of the riveting pin is cut. In the conventional riveting device, the power generated when the riveting pin is pulled is applied to the worm gear. The characteristics of the worm gear is to be used when a large reduction ratio of up to 50: 1 is required. To produce a large force of about 300 kg, the size of the worm gear must be very large. It had a problem that should be enlarged.

In order to solve this problem, the applicant has proposed a riveting power tool of the Republic of Korea Patent No. 10-352422.

In the above riveting power tool, the two handles are separately installed, and then the two handles are applied to the jaws, the jaws are rotated, and the jaws are pulled upward to raise the pin portion of the riveting pin. Breaking and riveting can be performed continuously.

In addition, it is possible to operate each operation individually, so that the drilling work as a riveting power tool, the riveting pin with a drill blade is automatically drilled through the hole, and the drill blade is not provided. The manual riveting operation can be performed by using a common riveting pin, and the square gear tooth used for power transmission can be used for power transmission so that the pulling force of the riveting pin can be small and powerful. Inner teeth or toothed teeth are available as an alternative.

However, since the riveting power tool still employs a complicated gear driving method, the structure is complicated, heavy, and expensive to manufacture.

In addition, as the riveting pin is provided with a drill blade, the manufacturing cost is inevitably expensive, and the strength of the drill blade is limited, so that there is a problem in that it is not suitable for use in riveting a steel plate having a predetermined thickness or more.

The present invention has been made to solve the problems of the prior art, the object of the present invention is to form a drill portion on one side of the handle, by forming a rivet on the opposite side of the drill, it is easy and simple to switch between drilling and riveting work To provide a drill-compatible hydraulic riveting power tool.

Another object of the present invention is to provide a drill-type hydraulic riveting power tool for the internal structure is made simple, and the riveting work force is improved by configuring the structure of the riveting device in a hydraulic drive method.

Still another object of the present invention is to provide a drill-hydraulic hydraulic riveting power tool that is light in weight and easy to use.

Combined hydraulic riveting power tool for achieving the object of the present invention forms a drill portion for drilling the construction hole in the work object on one side of the handle, the rivet portion operated by a hydraulic pump on the opposite side of the drill unit integrally It is characterized by forming.

And, the drill portion, a motor for generating power; A shaft gear 1 for outputting rotational power of the motor to a drill part side; A one-way clutch bearing 1 which is in contact with the shaft gear 1 and rotates in one direction; And a drill chuck pivotally connected to the one-way clutch bearing 1 and mounted with a drill blade.

And, the rivet portion, the shaft gear 2 for outputting the rotational power of the motor to the rivet portion side; One-way clutch bearing 2 which is in contact with the shaft gear 2 and rotates in one direction; Hydraulic pump assembly for receiving the rotational power from the one-way clutch bearing 2 to form a working hydraulic pressure; A piston drive part reciprocally operated by the hydraulic pressure of the hydraulic pump assembly; And an adapter installed at the front of the piston drive unit to mount the rivet pin.

In addition, the hydraulic pump assembly, the crank shaft which is rotated in axial connection with the one-way clutch bearing 2; A trocoid pump configured to rotate by receiving power from the crankshaft to suck hydraulic oil from the hydraulic tank into the hydraulic pump; A compression chamber for compression pumping hydraulic oil supplied from the trocoid pump; A hydraulic line 2 for transferring the high pressure hydraulic oil pumped from the compression chamber to the piston drive unit; And a hydraulic tank for supplying the hydraulic oil recovered from the piston drive unit to the trocoid pump.

At this time, the compression chamber is formed on the left and right sides of the inlet and outlet through which the hydraulic fluid enters, respectively, the inlet and outlet are opened and closed by the check valve 1 and the check valve 2, respectively, the center of the inlet and outlet to the rotational movement of the crank shaft A piston 1 interlocked vertically reciprocating is installed, and the piston 1 compresses and pumps hydraulic fluid to supply the piston drive unit.

In addition, the piston drive unit, the hydraulic cylinder for receiving hydraulic oil through the hydraulic line 2 from the hydraulic pump assembly; A piston 2 which is moved backward by the hydraulic oil pressure supplied from the front end of the hydraulic cylinder; And a spring installed inside the cylinder behind the piston 2 to elastically support the piston 2 to move forward.

And, the adapter is characterized in that the rivet jaw is installed so as to interlock with the piston 2 of the piston drive portion in the inner hollow.

The handle part may include a bidirectional switch lever for switching a drill part and a rivet part; A micro switch installed to precisely detect an operation state of the bidirectional switch lever; And a forward / reverse switch that receives the signal of the micro switch and controls the driving of the motor.

In addition, the lower end of the handle portion may be formed of any one of the power supply means selected from a power line or a charger.

The present invention forms a drill portion on one side of the handle, and by forming a rivet portion on the opposite side of the drill portion, it is possible to quickly and easily use the drill work and the riveting work alternately, it is possible to proceed quickly, and has an effect of shortening the construction period .

In addition, the present invention can be configured by the hydraulic drive method of the structure of the riveting device, it is possible to easily configure the internal structure, to reduce the number of parts used to reduce the production cost, and to reduce the weight of the power tool to use This has a handy effect.

Hereinafter, with reference to the accompanying drawings for a preferred embodiment of the present invention will be described in detail.

1 is an external view of a drill-type hydraulic riveting power tool of the present invention, Figure 2 is an internal structure diagram of a drill-hydraulic hydraulic riveting power tool of the present invention.

In the present invention as shown in the figure, the drill portion 10 is formed on one side of the handle portion 30, and the rivet portion 20 is integrally formed on the opposite side of the drill portion 10.

The configuration of the drill unit 10 will be described in detail as follows.

The drill unit 10 includes a motor 105 for generating power, a shaft gear 1 104 for outputting rotational power of the motor 105 to the drill unit 10 side, and the shaft gear 1 ( It consists of a one-way clutch bearing 1 (103) in contact with the 104 is rotated in one direction, and a drill chuck 102 is rotated in connection with the one-way clutch bearing 1 (103) and the drill blade 101 is mounted.

The configuration of the rivet 20 is described in detail as follows.

The configuration of the rivet portion 20, the shaft gear 2 (106) for outputting the rotational power of the motor 105 to the rivet portion 20 side, and the one-way clutch bearing which is in contact with the shaft gear 2 (106) rotates in one direction 2 (107), the hydraulic pump assembly 128 receives the rotational power from the one-way clutch bearing 2 (107) to form the hydraulic pressure, and the piston drive unit reciprocally operated by the hydraulic pressure of the hydraulic pump assembly 128 (21) and the adapter 127 is installed in front of the piston drive unit 21 to mount the rivet pin (126).

Here, if the configuration of the hydraulic pump assembly 128 of the rivet portion 20 will be described in detail, the configuration of the hydraulic pump assembly 128, the shaft is connected to the one-way clutch bearing 2 (107) crank shaft ( 110 and a trocoid pump 114 which is rotated under the power of the crankshaft 110 to suck the hydraulic oil 125 of the hydraulic tank 120 into the hydraulic pump, and is supplied from the trocoid pump 114. Compression chamber 113 for compression pumping hydraulic oil 125, hydraulic line 2 (116) for conveying the high pressure hydraulic fluid 125 pumped from the compression chamber 113 to the piston drive unit 21, and the piston drive unit ( It consists of a hydraulic tank 120 for supplying the hydraulic oil 125 recovered from the 21 to the trocoid pump (114).

In addition, the compression chamber 113 forms an inlet and an outlet through which the hydraulic oil 125 enters and exits on the left and right sides thereof, and the inlet and the outlet are opened and closed by the check valve 1 113a and the check valve 2 113b, respectively. In the center of the inlet and the outlet, a piston 1 (113c) which is vertically reciprocated in conjunction with the rotational movement of the crankshaft (110) is installed, the piston (113c) is the piston drive by compressing and pumping the operating oil (125) ) Will be supplied.

At this time, the check valve 1 (113a) and the check valve 2 (113b) is open when the flow of the hydraulic fluid 125 is moved forward to the outlet from the inlet side, it is made of a structure that does not open when the reverse flow.

Then, the configuration of the piston drive unit 21, the configuration of the piston drive unit 21, the hydraulic cylinder for receiving the hydraulic fluid 125 through the hydraulic line 2 (116) from the hydraulic pump assembly 128 ( 117, the piston 2 119 which is moved backward by the hydraulic oil 125 pressure supplied from the front end of the hydraulic cylinder 117, and the inside of the cylinder 117 rear of the piston 2 119. It consists of a spring 118 elastically supporting the piston 2 (119) to move forward.

Then, the configuration of the adapter 127, the adapter 127 is provided with a rivet jaw 121 to interlock with the piston 2 (119) of the piston drive unit 21 in the inner hollow.

The rivet jaw 121 performs a riveting operation by interlocking together when the piston 2 119 moves backward while chucking the rivet pin 126 mounted on the tip of the adapter 127.

At this time, the rivet jaw 121 and the piston 2 (119) is in a shaft-connected state, the shaft connection middle may be formed as a buffer member (spring).

The structure of the rivet pin 126 is to be used as the structure of the well-known, briefly described, the outer diameter member 126a and the outer diameter member which is inserted into the pre-drilled construction hole using the drill portion 10 By axially coupled to the center of the (126a) to move in the axial direction, the outer diameter member 126a is made of a core member (126b) to shrink and deform in the longitudinal direction, while expanding in the radial direction to be compressed in the construction hole.

At this time, the shim member 126b forms a grooved weakened portion 126c to be cut at the inner side of the outer diameter member 126a when the time exceeds a predetermined pressure.

Hereinafter, the configuration of the handle portion 30 will be described.

The handle 30 may include a bidirectional switch lever 108 for changing a drill part work and a rivet part work, and a micro switch 122 installed to precisely detect an operation state of the bidirectional switch lever 108. ) And a forward / reverse switch 123 for controlling the driving of the motor 105 by receiving the signal of the micro switch 122.

In this case, the micro switch 122 is mainly used for precise switching of a complicated circuit. In the present invention, the operation of the drill part 10 and the rivet part 20 of the bidirectional switch lever 108 are detected or In addition, by detecting the strength control state of the switch lever 108 to generate a signal for controlling the forward / reverse rotation and RPM (speed) of the motor 105.

The micro switch 122 has a structure connected to the forward / reverse switch 123 by the switch bracket 124.

A power supply means 40 is formed at the lower end of the handle part 30, and a power line or a charger may be used as the power supply means 40.

Hereinafter, the operation of the present invention having the configuration as described above will be described.

First, the construction hole is drilled in the object to be riveted using the drill unit 10.

At this time, when the operator selects and pushes the bidirectional switch lever 108 on the drill part 10 side formed in the handle part 30 for the drill operation, the micro switch 122 detects this and performs a forward / reverse switch ( Signal 123).

Thereafter, the forward / reverse switch 123 transmits a control signal to rotate the motor 105 forward.

The rotational power of the motor 105 is transmitted to the one-way clutch bearing 1 (103) through the shaft gear 1 (104) to rotate the drill chuck 102 and the drill blade 101 to puncture the construction hole.

After the drill operation is completed, the operator reverses the working direction of the power tool and then mounts the rivet pin 126 to the adapter 127, so that the mounted rivet pin 126 is inserted into the construction hole.

Subsequently, for the riveting operation, the operator selects and pushes the bidirectional switch lever 108 on the side of the rivet part 20 formed on the handle part 30, and the micro switch 122 detects this and reverses the forward / reverse switch. Signal 123.

Thereafter, the forward / reverse switch 123 transmits a control signal to rotate the motor 105 in the reverse direction.

At this time, the shaft gear 2 106 formed in the direction of the rivet portion 20 of the motor 105 is driven backward to drive the one-way clutch bearing 2 107.

Here, although the shaft gear 1 104 formed in the direction of the drill portion 10 of the motor 105 is driven backward together, the rotational power is not transmitted to the drill chuck 102 as it is idle at the one-way clutch bearing 1 103. .

Similarly, when the shaft gear 2 106 is driven in the forward direction, power transmission to the rivet part 20 is blocked as the one-way clutch bearing 2 107 is idling.

The power transmitted through the one-way clutch bearing 2 107 as described above will operate the hydraulic pump assembly 128 of the present invention.

At this time, looking at the operation structure of the rivet portion 20 with reference to Figures 3 and 4, the crankshaft 110 is rotated by receiving the rotational power from the one-way clutch bearing 2 (107), as shown in Figure 3, The trocoid pump 114 is operated by the rotational power of the crank shaft 110.

The trocoid pump 114 sucks the hydraulic oil 125 from the hydraulic tank 120 and transfers it to the compression chamber 113.

At this time, the conveying hydraulic fluid 125 is opened by the check valve 1 (113a) and supplied into the compression chamber 113, then pumped by the piston 1 (113c) interlocked with the crankshaft 110 to form a high pressure fluid. do.

The high-pressure hydraulic oil 125 opens the check valve 2 (113b) and is supplied to the hydraulic line 2 (116) is transferred to the hydraulic cylinder 117 of the piston drive unit 21.

The high pressure hydraulic fluid 125 supplied to the front end of the hydraulic cylinder 117 moves the piston 2 119 to the rear.

At this time, the piston 2 (119) is moved to the rear, to retreat together the axially coupled rivet jaw 121.

The rivet jaw 121 is retracted together in the state of chucking the core member 126b of the rivet pin 126. As the end of the core member 126b is retracted, the outer diameter surrounding the core member 126b outer diameter The member 126a is compressed to shrink in the longitudinal direction and expand in diameter in the circumferential direction so that the riveting operation is performed.

At this time, the core member 126b is designed to be sheared after the riveting, when the predetermined pressure is exceeded, the weak portion 126c.

Then, when the riveting operation is finished, the operator releases the two-way switch lever 108 so that the lever 108 is in the neutral position. At this time, the bidirectional switch lever 108 is coupled to a state in which the elastic force for maintaining the neutral state by the leaf spring 109 in the handle portion 30.

When the bidirectional switch lever 108 is in the neutral position, the operation of the motor 105 is stopped, and thus the operation of the hydraulic pump assembly 128 is stopped.

Therefore, the pressure of the hydraulic oil 125 applied to the piston drive part 21 is released, and the piston 2 119 is moved forward by the spring 118 restoring force.

At this time, the hydraulic oil 125 in the hydraulic cylinder 117 is discharged through the hydraulic line 2 (116) flows into the hydraulic pump assembly 128 side.

The hydraulic oil 125 introduced into the hydraulic pump assembly 128 is blocked by the check valve 2 113b and does not flow into the compression chamber 113, and the hydraulic line 2 is opened through the flow path through which the bypass pin 112 is opened. Discharged to 116 is recovered to the hydraulic tank (120).

At this time, the bypass pin 112 is connected to the lever 108 in a state capable of interlocking with the bidirectional switch lever 108, the lever 108 is made of a spring member having an elastic force.

The lever 108 pressurizes the bypass pin 112 when the rivet unit 20 is driven to prevent the inflow of the operating oil, and the pressure of the hydraulic oil 125 is stopped when the rivet unit 20 is stopped. Resilient support of the bypass pin 112 to be opened by.

5 is an external view of a drill-type hydraulic riveting power tool according to another embodiment of the present invention, the power tool of the present invention 120 ° drill part 10, the rivet part 20, the handle 30 to each other It can be arranged in a form that makes up.

The drill part 10 is positioned at the center of gravity of the handle part 30 and the rivet part 20 during the drill operation, so that stable drill operation is possible, and the handle part 30 and the drill part (in the riveting operation) Since the rivet part 20 is positioned at the center of gravity of 10), a stable riveting operation is possible.

1 is an external view of a drill-use hydraulic riveting power tool of the present invention.

Figure 2 is an internal structure of a drill-type hydraulic riveting power tool of the present invention.

3 and 4 are enlarged views showing the hydraulic actuation structure of the present invention.

Figure 5 is an external view of a drill-type hydraulic riveting power tool according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: drill part 20: rivet part

21: piston drive unit 30: handle 40: power supply 101: drill blade

102: drill chuck 103: one-way clutch bearing 1

104: shaft gear 1 105: motor

106: shaft gear 2 107: one-way clutch bearing 2

108: lever 109: leaf spring

110: crankshaft 111: switch lever

112: bypass pin 113: compression chamber

113a: check valve 1 113b: check valve 2

113c: Piston 1 114: Trocoid Pump

115: hydraulic line 1 116: hydraulic line 2

117: hydraulic cylinder 118: spring

119: piston 2 120: hydraulic tank

121: rivet jaw 122: micro switch

123: forward / reverse switch 124: switch bracket

125: working fluid 126: rivet pin

126a: outer diameter member 126b: core member

126c: Vulnerability 127: Adapter

128: hydraulic pump assembly

Claims (10)

A handle part 10 formed on one side of the handle part 30 to drill a construction hole in the work object; A rivet part 20 integrally formed on the opposite side of the drill part 10 and operated by a hydraulic pump; Is formed on the lower end of the handle portion 30 and includes any one of the power supply means 40 selected from a power line or a charger, The rivet portion 20, A shaft gear 2 106 that outputs rotational power of the motor 105 to the rivet portion 20 side; A one-way clutch bearing 2 107 which is in contact with the shaft gear 2 106 and rotates in one direction; Hydraulic pump assembly 128 for receiving the rotational power from the one-way clutch bearing 2 (107) to form a working hydraulic pressure; A piston drive unit reciprocating by the hydraulic pressure of the hydraulic pump assembly 128; And an adapter 127 installed at the front of the piston driving unit 21 to mount the rivet pin 126 and having a rivet jaw 121 at an inner hollow portion thereof. The handle portion 30, A bidirectional switch lever 108 for switching drill operations and rivet operations; A micro switch 122 installed to precisely detect an operation state of the bidirectional switch lever 108; And a forward / reverse switch 123 for receiving a signal from the micro switch 122 to control driving of the motor 105. The drill unit 10, A motor 105 for generating power; A shaft gear 1 (104) for outputting rotational power of the motor (105) to a drill portion (10) side; A one-way clutch bearing 1 103 that is in contact with the shaft gear 1 104 and rotates in one direction; And a drill chuck 102 that is axially connected to the one-way clutch bearing 1 103 and rotated and mounted with a drill blade 101. The hydraulic pump assembly 128, A crank shaft 110 axially connected to the one-way clutch bearing 2 107 to rotate; A trocoid pump (114) configured to rotate by receiving power from the crankshaft (110) to suck the hydraulic oil (125) of the hydraulic tank (120) into the hydraulic pump; A compression chamber 113 for compression pumping the hydraulic oil 125 supplied from the trocoid pump 114; A hydraulic line 2 116 for transferring the high pressure hydraulic oil pumped from the compression chamber 113 to the piston drive unit 21; And a hydraulic tank (120) for supplying the hydraulic oil (125) recovered from the piston drive unit (21) to the trocoid pump (114). delete delete delete The method of claim 1, The compression chamber 113 forms an inlet and an outlet through which the hydraulic oil 125 enters and exits, respectively, on the left and right sides thereof, and the inlet and the outlet are opened and closed by the check valve 1 113a and the check valve 2 113b, respectively. Piston 1 (113c) is installed in the center of the inlet and outlet in the vertical reciprocating operation in conjunction with the rotational movement of the crank shaft 110, the piston 1 (113c) is pumped by the hydraulic oil 125 to the piston drive unit 21 Combined hydraulic hydraulic riveting power tool characterized in that the supply. The method of claim 1, The piston drive unit 21, A hydraulic cylinder 117 receiving hydraulic oil 125 from the hydraulic pump assembly 128 through the hydraulic line 2 116; A piston 2 119 which is moved backward by the pressure of the hydraulic oil 125 supplied from the front end of the hydraulic cylinder 117; And And a spring 118 installed in the cylinder 117 at the rear of the piston 2 119 to resiliently support the piston 2 119 to move forward. 2. delete delete delete delete

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