KR102298072B1 - Conversion Module - Google Patents

Abstract

The motor of the present invention, a conversion module used in a power tool having a gear housing in which a reduction gear unit for reducing the driving force of the motor is accommodated, includes: a tool shaft that receives the reduced driving force and performs an operation; A torque limit part formed of a spring holder coupled to a conversion handle for operating the generated torque and operation mode, and moving in the axial direction in conjunction with the conversion handle, and a torque spring disposed in contact with one side of the spring holder to provide a compressive force ; and an impact generating unit coupled to the tool shaft to convert the rotational driving force of the motor into an axial reciprocating motion of the tool shaft, wherein the impact generating unit is coupled to the spring holder and includes: a housing in which a conversion line is formed; a ratchet rotor having a conversion pin moving along the conversion line; a first ratchet fixedly coupled to the tool shaft; a second ratchet fixedly coupled to the ratchet rotor and installed to be movable in the axial direction of the tool shaft; and a ratchet spring having one end fixed to the inner circumferential surface of the ratchet rotor, and the other end being in contact with the second ratchet to press the second ratchet away from the first ratchet. It is characterized in that the impact is generated in the axial direction of the tool shaft by the coupling of the ratchet and the second ratchet, so that the size of the torque and the working mode can be changed by the conversion handle, thereby improving product productivity and reliability.

Description

Conversion Module

The present invention relates to a conversion module used in a power tool, and more particularly, to a conversion module capable of converting a working mode of a power tool to a drill mode, a driver mode, and an impact mode.

A power tool is a tool that can be used for various purposes according to the purpose of work such as hammers, drivers and drills by driving a motor using electricity as a power source through a wire or a battery.

Among them, in the case of hammer work, the rotational motion of the tool shaft, which is connected to the motor and rotates, is converted into an axial vibration motion of the tool shaft to facilitate work on a hard object. However, in the case of a driver operation or a drilling operation, it is preferable to limit the axial vibration of the tool shaft by using the rotational force of the tool shaft.

In addition, in order to prevent damage to bolts or screws due to excessive torque being applied to the bit during driver work, a torque limiting device that blocks the transmission of more than a certain torque is applied to power tools. However, it is desirable to limit the torque limiting device because a high torque is required for drilling or hammering.

As such, as the need to selectively activate or deactivate the impact generating device and the torque limiting device according to the work has emerged, most power tools have a configuration that generates axial vibration and a configuration that blocks driving force.

However, as various configurations are applied, the number and size of parts of the power tool increase, and the user's convenience decreases as the operation becomes more complicated, and as the production process becomes more complicated, productivity and product reliability This lowering problem occurred

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a conversion module with improved product productivity and reliability by simplifying the conversion and operation structure.

The conversion module used in the motor of an embodiment of the present invention, a power tool having a gear housing in which a reduction gear unit for reducing the driving force of the motor is accommodated, includes: a tool shaft that receives the reduced driving force and performs an operation; A torque limit portion formed of a spring holder coupled to a conversion handle for operating the generated torque and operation mode, and moving in the axial direction in conjunction with the conversion handle, and a torque spring disposed in contact with one side of the spring holder to provide a compressive force ; and an impact generating unit coupled to the tool shaft to convert the rotational driving force of the motor into axial reciprocating motion of the tool shaft, wherein the impact generating unit is coupled to the spring holder and includes: a housing in which a conversion line is formed; a ratchet rotor having a conversion pin moving along the conversion line; a first ratchet fixedly coupled to the tool shaft; a second ratchet fixedly coupled to the ratchet rotor and installed to be movable in the axial direction of the tool shaft; and a ratchet spring having one end fixed to the inner circumferential surface of the ratchet rotor, and the other end contacting the second ratchet and pressing the second ratchet in a direction away from the first ratchet. It is characterized in that the impact is generated in the axial direction of the tool shaft by the coupling of the ratchet and the second ratchet.

It may further include; a first fastening part coupled to the torque limit part, and a housing cover formed in the first fastening part and having a fastening line on which the conversion pin is disposed, wherein the spring holder is recessed from the inner circumferential surface A first fastening groove engaged with the first fastening part may be formed, and the impact generating part may be activated or deactivated by interlocking with the conversion handle.

The fastening line may be formed of a first line formed so that the conversion pin is movable in the axial direction, and a second line extending from the first line so that the conversion pin is rotatable about the tool axis, and the When the ratchet rotor rotates around the tool shaft, the housing slides with the first lifting protrusion protruding from one side of the second ratchet and raising the second ratchet to form a second lifting protrusion for coupling with the first ratchet. can

The spring holder may be recessed into the inner circumferential surface to form a second fastening groove fastened to the housing, and the housing may have a conversion protrusion selectively fastened to the second fastening groove formed therein, depending on whether the conversion protrusion is fastened or not. The torque limit bookkeeping can be activated or deactivated.

The first ratchet and the second ratchet may be provided with concave-convex portions that engage each other on surfaces facing each other, so that the tool shaft fixed to the first ratchet may reciprocate in an axial direction.

As described above, according to the problem solving means of the present invention, various effects including the following items can be expected. However, the present invention is not established only when exhibiting all of the following effects.

The conversion module of the present invention reduces the cost required for production and maintenance by minimizing the number of parts for changing the working mode, and at the same time simplifies the assembly process to minimize damage that may occur in the production process to significantly improve the productivity and reliability of the product. have an effect

In addition, by using one conversion handle, it is possible to operate torque operation and various operation mode conversions, thereby providing improved convenience to the user.

In addition, the ratchet spring for generating a compressive force in the axial direction is provided to minimize the axial vibration transmitted to the operator in the shaft driver operation or the drill operation, thereby significantly reducing the fatigue of the operator.

1 is an exploded perspective view of a power tool to which a conversion module of the present invention is applied.
Figure 2 is a perspective view of the conversion module of the present invention.
Figure 3 is an exploded perspective view of Figure 2;
4 is a perspective view and a cross-sectional view when the conversion module of FIG. 2 is in a driver mode;
Figure 5 is a perspective view and a cross-sectional view when the conversion module of Figure 2 in a drill mode.
Figure 6 is a perspective view and a cross-sectional view when the conversion module of Figure 2 is in hammer mode.
Figure 7 is a view showing the movement of the first and second ratchet when the hammer mode conversion in the cross-sectional view of Figure 6;
Figure 8 is a view showing an assembly sequence of the conversion module of Figure 2;

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

However, detailed descriptions of known functions or configurations in the detailed description are omitted so as not to obscure the gist of the present invention.

1 is an exploded perspective view of a power tool to which the conversion module of the present invention is applied, FIG. 2 is a perspective view of the conversion module of the present invention, and FIG. 3 is an exploded perspective view of FIG. 4 is a perspective view and a cross-sectional view when the conversion module of FIG. 2 is in a driver mode, FIG. 5 is a perspective view and a cross-sectional view when the conversion module of FIG. 2 is in a drill mode, and FIG. 6 is a perspective view when the conversion module of FIG. 2 is in a hammer mode and a cross-sectional view, FIG. 7 is a view illustrating the movement of the first and second ratchets when the hammer mode is changed in the cross-sectional view of FIG. 6 .

1 to 7, the motor 200 according to an embodiment of the present invention, a gear housing 300 in which a reduction gear for reducing the driving force of the motor 200 is accommodated is used in the power tool 10 used in The conversion module 100 is coupled to the conversion handle 400 that operates the tool shaft 110 generated torque and the work mode for performing the work by receiving the decelerated driving force, and is linked to the conversion handle 400 to move in the axial direction The spring holder 121, the torque limit portion 120 formed of a torque spring 122 disposed in contact with one side of the spring holder 121 to provide a compressive force, and the tool shaft 110 are coupled to the and an impact generating unit 130 for converting the rotational driving force of the motor 200 into an axial reciprocating motion of the tool shaft 110, wherein the impact generating unit 130 is fastened with the spring holder 121, A housing 131 in which a conversion line 1311 is formed, a ratchet rotor 132 in which a conversion pin 1321 moving along the conversion line 1311 is formed, and a first ratchet 133 fixedly coupled to the tool shaft 110 . ), the second ratchet 134 and one end fixedly coupled to the ratchet rotor 132 and installed to be movable in the axial direction of the tool shaft 110 are fixed to the inner circumferential surface of the ratchet rotor 132, the other The end includes a ratchet spring 135 formed to abut against the second ratchet 134 and press the second ratchet 134 in a direction away from the first ratchet 133 , and the first ratchet 133 . ) and the second ratchet 134, characterized in that the impact is generated in the axial direction of the tool shaft (110).

At this time, a housing cover in which a first fastening part 141 coupled to the torque limit part 120 and a fastening line 142 formed in the first fastening part 141 and on which the conversion pin 1321 is disposed are formed. It is preferable to further include (140).

The motor 200 uses electricity as a driving force and is connected to the tool shaft 110 through the gear housing 300 to rotate the tool shaft 110 . At this time, the gear housing 300 is accommodated therein a reduction gear for reducing the driving force of the motor 200 , and attenuates the driving force transmitted to the tool shaft 110 .

The tool shaft 110 is a shaft that is the center of movement of the power tool 10, and one end is connected to one side of the gear housing 300, and the reduced driving force is transmitted and various operations are performed through the tool connected to the other end. let it do

Therefore, the tool shaft 110 is disposed through each configuration of the present invention, and is connected to a specific configuration to work in driver mode, drill mode and hammer mode depending on whether the torque limit part 120 and the impact generator 130 are active. carry out

The torque limit unit 120 includes a spring holder 121 that is moved in the axial direction in association with the operation of the conversion handle 400, a torque spring 122 that generates a compressive force as the spring holder 121 moves, and a torque It is formed of a clutch plate 123 supporting the other side of the spring 122 .

The spring holder 121 has a screw groove 1211 formed along the outer circumferential surface, and the screw groove 1211 is coupled to the screw thread 410 formed along the inner circumferential surface of the conversion handle 400 to the degree of operation of the conversion handle 400 . , it moves in the axial direction according to the degree of rotation of the user.

In addition, a first fastening groove 1212 coupled to the housing cover 140 and a second fastening groove 1213 coupled to the housing 131 are formed along the inner circumferential surface to form a conversion handle 400 and a torque limit unit 120 . and the conversion handle 400 and the impact generating unit 130 are interlocked, and a spring receiving unit 1215 on which the torque spring 122 is seated is formed on one side to prevent the torque spring 122 from being separated.

At this time, a plurality of first fastening grooves 1212 and second fastening grooves 1213 are formed alternately with each other so that a fixing force of a certain level or more is generated and the operation mode can be converted more stably.

The first fastening groove 1212 and the second fastening groove 1213 of an embodiment are each formed in four pieces, and each of the first and second fastening grooves 1212 and 1213 is formed at intervals of approximately 90 degrees to the housing cover 140 . And it is more stably fastened to the housing 131 .

Specifically, the first fastening groove 1212 is formed to correspond to the position of the first fastening part 141 , and is fixedly coupled to the first fastening part 141 so that the housing cover 140 is fixed, and the second fastening groove 1213 is formed to correspond to the position of the conversion protrusion 1315 , and the conversion protrusion 1315 is seated to fix the housing 131 so as not to rotate around the tool shaft 110 in the driver mode.

However, when the driver mode is converted to the drill mode, the spring holder 121 is disposed so that the torque spring 122 is maximally compressed, and accordingly, the conversion protrusion 1315 is separated from the second fastening groove 1213 . At this time, by the additional rotation of the conversion handle 400, the spring holder 121 is rotated and at the same time is further moved in the direction of the tool shaft 110, and the conversion protrusion 1315 is moved to the upper side of the second fastening part 143, Accordingly, the housing cover 140 is moved a predetermined distance in the axial direction of the tool shaft 110 and the power tool 10 is converted from the driver mode to the drill mode.

Accordingly, a seating surface 1214 on which the conversion protrusion 1315 is seated in the drill mode is formed on one side of the second fastening part 143 .

One end of the torque spring 122 is in contact with one side of the spring holder 121 , and the other end is fixed in contact with the clutch plate 123 . At this time, a spring seat 1215 surrounding one end of the torque spring 122 is formed on one side of the spring holder 121 to prevent separation.

Therefore, the torque spring 122 generates a compressive force according to the extent to which the spring holder 121 moves in the axial direction of the tool shaft 110 to limit the maximum torque transmitted to the tool shaft 110 . Accordingly, the operator limits the torque provided according to the purpose and purpose of the work to prevent overload.

Accordingly, it has the effect of preventing damage to bolts or screws due to excessive torque and enabling more accurate work to ensure work precision and improve worker stability.

The clutch plate 123 is disposed on the opposite side of the spring holder 121 so as to be in contact with the other end of the torque spring 122 so that the torque spring 122 can be compressed. The plate ball 125 disposed on the guide plate 124 is formed to be in contact, and when the torque transmitted to the tool shaft 110 is equal to or greater than the set torque value, the driving force transmitted to the tool shaft 110 is blocked.

Specifically, when the conversion handle 400 is rotated in the direction in which the number displayed on the conversion handle 400 increases, the spring holder 121 moves in the direction of compressing the torque spring 122, and the compressive force of the torque spring 122 increases. and the maximum torque transmitted to the tool shaft 110 is also increased. Conversely, when the conversion handle 400 is rotated in a direction in which the number displayed on the conversion handle 400 becomes smaller, the spring holder 121 moves in the direction in which the compression of the torque spring 122 is released, and the compression force of the torque spring 122 is released. is reduced and the maximum torque transmitted to the tool shaft 110 is reduced.

At this time, a guide plate 124 , a plate ball 125 , a ring gear 126 , a ring gear ball 127 , and a ball support pin 128 are disposed on one side of the clutch plate 123 , and the torque spring 122 . The torque transmitted to the tool shaft 110 in the driver mode is limited according to the compression force.

`Therefore, the present invention is provided with the torque limit unit 120 interlocked with the conversion handle 400, so that the operator can more easily control the required torque to prevent damage that may occur to the work piece and the power tool 10 during work. It has the effect of improving the completeness of work and product durability by minimizing it.

The impact generating unit 130 is activated in the hammer mode in a configuration to convert the rotational motion of the motor 200 into the axial motion of the tool shaft 110 as the first and second ratchets 133 and 134 are coupled. Specifically, the impact generating unit 130 includes a housing 131 in which a conversion line 1311 is formed, a ratchet rotor 132 that rotates to activate or deactivate the impact generating unit 130 , and a tool shaft 110 that is fixedly coupled to the first. 1 Ratchet 133, a second ratchet 134 installed to be movable in the axial direction of the tool shaft 110, and a ratchet spring 135 for pressing the second ratchet 134 away from the first ratchet 133 ) is formed from

The housing 131 has a conversion line 1311 on which the conversion protrusion 1315 moves along the outer circumferential surface, and a second lifting protrusion ( 1311 ) for moving the second ratchet 134 in the axial direction of the tool shaft 110 inside. 1314) is formed. In addition, a conversion protrusion 1315 protruding from the outer circumferential surface to change the working mode is formed, and a fixing protrusion 1316 protruding from one side and fitted to the fixing washer 500 is formed.

The conversion line 1311 extends from one end of the housing 131 and is bent at one side so that the power tool 10 can be operated in a corresponding working mode according to the position of the conversion pin 1321 . In other words, the first line 1312 extending in the axial direction of the tool shaft 110 from one end to enable axial coupling with the ratchet rotor 132 to which the conversion pin 1321 is coupled, and the ratchet rotor 132 are The second line 1313 is bent and extended from the first line 1312 so as to be rotatable at a predetermined angle about the tool shaft 110 .

The second lifting protrusion 1314 is formed repeatedly spaced apart by a predetermined distance along the inner circumferential surface of the housing 131 , and protrudes in the axial direction of the tool shaft 110 , and is formed to have second inclined surfaces 13141 on both sides, the ratchet rotor When the 132 rotates around the tool shaft 110 , the second ratchet 134 slides with the first inclined surface 13421 of the first lifting protrusion 1342 formed on one side of the second ratchet 134 . The first ratchet 133 is coupled by moving it in the direction.

In other words, the second lifting projection 1314 is formed such that the second inclined surface 13141 is in contact with the first inclined surface 13421 of the first lifting projection 1342 in the driver mode and the drill mode, and in the hammer mode, the ratchet rotor 132 ), the first inclined surface 13421 and the second inclined surface 13141 slide to each other and the opposite surfaces of the first and second projections are in contact with each other by the rotation.

The conversion protrusion 1315 is formed to protrude from the outer circumferential surface of the housing 131, is coupled to the second fastening groove 1213 in the driver mode, and is separated from the second fastening groove 1213 in the drill mode to the seating surface 1214. is settled Specifically, the conversion protrusion 1315 rotates the spring holder 121 according to the additional rotation of the conversion handle 400 , and forms a seating portion and one end of the housing cover 140 according to the axial movement of the tool shaft 110 . It is fixed in contact with one side at the same time.

At this time, the conversion protrusion 1315 is seated on the seating portion and at the same time moves the housing cover 140 in the axial direction of the tool shaft 110 by a predetermined distance to move the conversion pin 1321 to the first line 1312 and the second line 1313 . ) at the end where they meet.

Accordingly, the spring holder 121 releases the torque limit transmitted to the tool shaft 110 so that the torque spring 122 is fixed in a state with the maximum compressive force. The working mode of the power tool is thus converted into a drilling mode that can apply maximum torque to the workpiece without restrictions.

The fixing protrusion 1316 extends in the axial direction of the tool shaft 110 from one end and is fitted to the fixing washer 500 so that the housing 131 is not rotated along the tool shaft 110 to limit the first and second ends. It prevents the ratchets 133 and 134 from being arbitrarily engaged. Accordingly, the power tool 10 using the conversion module of the present invention provides more improved workability by limiting the axial movement of the tool shaft 110 in the driver mode and the drill mode.

The support end 1317 protrudes outwardly from one end of the housing 131 and is a portion on which one end of the housing cover 140 is seated, so that it can be more stably coupled with the housing cover 140 to improve product durability. .

The ratchet rotor 132 is coupled to the conversion pin 1321 along the outer circumferential surface, and is disposed inside the housing 131 to keep the first and second ratchets 133 and 134 spaced apart in the driver mode and the drill mode, and the hammer In the mode, the first and second ratchets 133 and 134 are maintained in a coupled state.

Therefore, the ratchet rotor 132 has a predetermined price along the outer circumferential surface and a pin coupling groove 1322 to which the conversion pin 1321 is coupled is formed, and the inner circumferential surface has a seating end 1323 on which one end of the ratchet spring 135 is seated. this is formed

The conversion pin 1321 is disposed to protrude outward and sequentially pass through the conversion line 1311 and the fastening line 142 . Specifically, the conversion pin 1321 sequentially passes through the first line 1312 and the fastening line 142 in the driver mode, and the first line 1312 and the second line 1313 meet at the same time as the fastening line 142 . is located at the end of At this time, the conversion pin 1321 is disposed between the first line 1312 and the fastening line 142 and is fixed so as not to move along the second line 1313 .

In addition, the conversion pin 1321 is located in the same position as in the driver mode in the drill mode, but the housing cover 140 is moved in the axial direction of the tool shaft 110 by the separation of the conversion protrusion 1315 to the second line 1313 ) is released so that it can be moved along.

In the hammer mode, the conversion pin 1321 is moved along the second line 1313 by the rotation of the ratchet rotor 132, and the second elevating protrusion 1314 formed on the second ratchet 134 is the first elevating protrusion ( 1342 , the second ratchet 134 is raised by sliding, and the tool shaft 110 is lowered by the pressure of the operator to couple the first ratchet 133 and the second ratchet 134 .

At this time, the conversion pin 1321 is preferably formed in plurality for smooth and stable rotation of the ratchet rotor 132, and the four conversion pins 1321 are coupled to the ratchet rotor 132 of one embodiment, and the conversion pin ( 1321) are preferably arranged to be spaced apart from each other by a predetermined interval. Accordingly, a plurality of pin coupling grooves 1322 are also formed to be spaced apart from each other by a predetermined interval.

The seating end 1323 is formed to protrude from the inner surface so that the ratchet spring 135 is stably seated inside the ratchet rotor 132, so that the first and second ratchets 133 and 134 are not coupled to each other in the driver mode and drill mode. make it possible

The first ratchet 133 is fixed to the tool shaft 110 and rotated together, but does not move in the axial direction of the tool shaft 110, and the second ratchet 134 is fixed to the ratchet rotor 132 and fixed to the housing ( 131) It engages with the second lifting protrusion 1314 formed therein and is movable in the axial direction of the tool shaft 110 , but is not fixed to the tool shaft 110 .

At this time, the first ratchet 133 has a first concave-convex portion 1331 formed on a surface opposite to the second ratchet 134 , and the second ratchet 134 is formed on a surface opposite to the first ratchet 133 . The concavo-convex portion 1342 is formed to generate reciprocating motion in the axial direction of the tool shaft 110 by complementary coupling of the first concave-convex portion 1331 and the second concave-convex portion 1342 .

Specifically, in the first and second concave-convex portions 1331 and 1341 , rising surfaces 13311 and 13411 and descending surfaces 13312 and 13412 are repeatedly formed, and when the first and second ratchets 133 and 134 are coupled, the first and second Each of the rising surfaces 13311 and 13411 and each of the descending surfaces 13312 and 13412 formed on the uneven portions 1331 and 1341 are coupled to each other so as to be in contact with each other. In other words, in a state in which the first and second ratchets 133 and 134 are coupled, each of the descending surfaces 13312 and 13412 is dropped by the rotational movement of the first ratchet 133, and in a state in which the respective ascending surfaces 13311 and 13411 are in contact. As it slides, the second ratchet 134 is moved in the axial direction of the tool shaft 110 so as to move away from the first ratchet 133 , and each of the rising surfaces 13311 and 13411 and each of the descending surfaces 13312 and 13412 come into contact with each other again. As the second ratchet 134 hits the first ratchet 133 , it generates an impact in the axial direction of the tool shaft 110 .

In addition, a first lifting protrusion 1342 extending in the axial direction of the tool shaft 110 is formed on a surface opposite to the surface on which the second concave-convex portion 1342 is formed of the second ratchet 134 , and the ratchet rotor 132 is formed. The second ratchet 134 is moved in a direction closer to the first ratchet 133 by sliding with the second lifting protrusion 1314 formed on the inner circumferential surface of the housing 131 by the rotation of the housing 131 .

Accordingly, in order to smooth the sliding of the first and second lifting protrusions 1342 and 1314, first inclined surfaces 13421 are formed on both sides of the first lifting protrusions 1342, and the second lifting protrusions 1314 are formed on both sides. A second inclined surface 13141 is formed.

Specifically, the first and second inclined surfaces 13421 and 13141 are formed to be inclined in the same direction when the first and second lifting projections 1342 and 1314 are engaged, but the first and second lifting projections 1342 and 1314 are formed to be inclined in the same direction. When they are slid and are separated from each other, they are formed to be inclined in different directions.

The ratchet spring 135 is disposed inside the ratchet rotor 132, one end is in contact with the seating end 1323 and the other end is formed to be in contact with one surface of the second ratchet 134, the second ratchet 134. is pressed in a direction away from the first ratchet 133 to prevent the first and second ratchets 133 and 134 from being arbitrarily coupled. This makes it more stable to work in driver mode or drill mode.

The housing cover 140 is engaged with the torque limit unit 120 and the impact generating unit 130, respectively, so that the torque limit unit 120 and the impact generating unit 130 are interlocked by the operator's operation of the conversion handle 400 to be active or make it inactive.

Accordingly, the housing cover 140 has a first fastening part 141 fastened to the torque limit part 120 and a fastening line 142 fastened to the conversion pin 1321 are formed, and between the first fastening parts 141 , The conversion protrusion 1315 is positioned and the second fastening part 143 formed in a predetermined space is formed so as to be able to rotate around the tool shaft 110 at a predetermined angle. Here, the second fastening part 143 corresponds to a space that is inevitably generated according to the first fastening part 143, but it is divided for convenience of description.

Specifically, the first fastening part 141 extends in the direction in which the tool shaft 110 extends from one end and is fitted into the first fastening groove 1212 to prevent the ratchet rotor 132 from rotating in the driver mode. To provide a more stable operation. In addition, the second fastening part 143 is formed between the first fastening parts 141 to provide a space in which the conversion protrusion 1315 is located, and at the same time, the spring holder 121 is further moved, and the driver mode is changed from the driver mode to the drill mode. In this case, the conversion protrusion 1315 may be seated on the seating surface 1214 .

Therefore, the conversion module 100 of the present invention allows the torque control and work mode to be converted by the operation of one conversion handle 400, thereby simplifying the internal structure of the power tool 10 and the number of required parts. It has the effect of significantly improving the productivity of the product by reducing

In addition, according to this, miniaturization and weight reduction of the power tool 10 are realized, and the cost of the product and the man-hours of the production operation are significantly reduced, thereby maximizing the effect of improving the productivity of the product and the convenience of the operator.

FIG. 8 is a diagram illustrating an assembly sequence of the conversion module of FIG. 2 . With reference to FIG. 8, the assembly sequence of the conversion module 100 according to an embodiment of the present invention will be described in detail.

The conversion module 100 of an embodiment of the present invention couples the conversion pin 1321 to the pin coupling groove 1322 formed in the ratchet rotor 132 . At this time, in order to improve the fastening force of the conversion module 100 and ensure stable module conversion, four conversion pins 1321 are formed, and the pin coupling grooves 1322 are formed in all directions spaced apart from the tool shaft 110 by the same distance.

In addition, by inserting and fixing the bearing to one side of the housing 131 , the torque limit unit 120 and the impact generating unit 130 do not rotate together with the tool shaft 110 . However, the first ratchet 133 of the impact generating unit 130 is fixed to the tool shaft 110 and rotates together.

Insert the ratchet spring 135 into the inside of the ratchet rotor 132 so that one end of the ratchet spring 135 is caught and fixed to the seating end 1323, and the second ratchet 134 is disposed on the other side of the spring. . At this time, a seating protrusion 1343 is formed on the outer circumferential surface of the second ratchet 134 to be seated in the seating groove 1324 formed at one end of the ratchet rotor 132 by protruding.

Accordingly, the second ratchet 134 is fixed to the ratchet rotor 132 at the same time receiving the pressing force by the ratchet sprite and does not rotate together with the tool shaft 110, but is installed to be movable in the axial direction of the tool shaft 110. .

The ratchet rotor 132 in which the ratchet spring 135 and the second ratchet 134 are installed is inserted into the housing 131 and disposed. At this time, the conversion pins 1321 move along the first line 1312 formed extending in the direction in which the ratchet rotor 132 is coupled at the same time and are fastened to each other. Accordingly, the first line 1312 is also formed on all four sides with the tool axis 110 as the center.

When the housing 131 and the ratchet rotor 132 are engaged, the clutch plate 123 , the torque spring 122 and the spring holder 121 are sequentially positioned outside the housing 131 . At this time, one end of the torque spring 122 is seated on the spring seat portion 1215 formed on one side of the spring holder 121 , and the other end is placed in contact with the clutch plate 123 , and the housing 131 . The conversion protrusion 1315 formed on the outside is positioned in the second fastening part 143 formed in the spring holder 121 so that it is attached to the torque spring 122 according to the axial movement of the tool shaft 110 of the spring holder 121 . compression force is generated.

When the housing 131, the ratchet rotor 132, and the torque limit part 120 are coupled, the fastening line 142 corresponds to the position of the protruding conversion pin 1321, so that the torque limit part 120 and the housing ( 131) assembling the housing cover 140 between them. At this time, the first fastening part 141 in which the fastening line 142 is formed is positioned in the first fastening groove 1212 formed in the spring holder 121 .

In other words, the housing cover 140 is fastened with each of the torque limit unit 120 and the impact generating unit 130 through the first fastening part 141 and the fastening line 142 , and the torque is generated by the operation of the conversion handle 400 . The limit unit 120 and the impact generating unit 130 are interlocked and are in an active or inactive state so that the torque and work mode can be manipulated.

A hole is formed at one end of the tool shaft 110 to be recessed into the inside to fix a tool suitable for various tasks, and a spring, a washer 500, a ball bearing 600 and a first ratchet 133 are inserted at the other side. and is fixed Therefore, the first ratchet 133 is fixed to the tool shaft 110 and is formed to rotate together with the tool shaft 110 .

The tool shaft 110 passes through the washer 500 and the ratchet rotor 132 , and on one side of the tool shaft 110 , a fixing washer 510 having a fixing hole 511 is disposed so that the housing 131 . It is combined with the fixing protrusion 1316 protruding from one end to form the conversion module 100 .

As described above, the conversion module 100 of the present invention operates one conversion handle 400 to activate or deactivate the torque limit unit 120 and the impact generating unit 130, thereby improving productivity and improving user convenience. make it

In the above, preferred embodiments of the present invention have been exemplarily described, but the scope of the present invention is not limited to such specific embodiments, and it is within the protection scope of the present invention that can be appropriately changed within the scope described in the claims. corresponds to

10 power tools
100 Conversion module 110 Tool shaft 120 Torque limit part
121 Spring holder 1211 Screw groove 1212 First fastening groove
1213 Second fastening groove 1214 Seating surface 1215 Spring seating part
122 Torque spring 123 Clutch plate 124 Guide plate
125 Plate Ball 126 Ring Gear 127 Ring Gear Ball
128 ball support pins
130 Impact generator 131 Housing 1311 Conversion line
1312 1st line 1313 2nd line 1314 2nd lifting projection
13141 2nd inclined surface 1315 Conversion projection 1316 Fixing projection
1317 support group
132 Ratchet rotor 1321 Conversion pin 1322 Pin coupling groove
1323 Seating end 1324 Seating groove
133 1st ratchet 1331 1st uneven part
13311,13411 rising side 13312,13412 falling side
134 2nd ratchet 1341 2nd concave-convex part 1342 1st lifting projection
13421 1st slope 1343 Seating projection 135 Ratchet spring
140 Housing cover 141 First fastening part 142 Fastening line
143 second fastening part
200 motor 300 gear housing
400 Conversion handle 410 Thread
500 washer 510 fixing washer 511 fixing hole
600 ball bearings

Claims (5)

In the conversion module 100 used in a motor 200, a power tool provided with a gear housing 300 in which a reduction gear for reducing the driving force of the motor 200 is accommodated,
The reduced driving force is transmitted to the tool shaft 110 to perform the work;
A spring holder 121 coupled to the conversion handle 400 for operating the generated torque and working mode, the spring holder 121 moving in the axial direction in conjunction with the conversion handle 400, and disposed in contact with one side of the spring holder 121 Torque limit portion 120 formed of a torque spring 122 to provide a compressive force; and
and an impact generating unit 130 coupled to the tool shaft 110 to convert the rotational driving force of the motor 200 into an axial reciprocating motion of the tool shaft 110;
The impact generating unit 130 is
a housing 131 coupled to the spring holder 121 and having a conversion line 1311 formed thereon;
a ratchet rotor 132 in which a conversion pin 1321 moved along the conversion line 1311 is formed;
a first ratchet 133 fixedly coupled to the tool shaft 110;
a second ratchet 134 fixedly coupled to the ratchet rotor 132 and installed to be movable in the axial direction of the tool shaft 110; and
One end is fixed to the inner circumferential surface of the ratchet rotor 132 , and the other end abuts against the second ratchet 134 to press the second ratchet 134 away from the first ratchet 133 . Conversion module, comprising a ratchet spring (135), characterized in that the impact is generated in the axial direction of the tool shaft (110) by the coupling of the first ratchet (133) and the second ratchet (134) (100).
According to claim 1,
The housing cover ( 140); further comprising;
The spring holder 121 is
A first fastening groove 1212 that is recessed from the inner circumferential surface and engages with the first fastening part 141 is formed, and the impact generating part 130 is activated or deactivated by interlocking with the conversion handle 400. A conversion module 100 that does.
3. The method of claim 2,
The conversion line 1311 is
A first line 1312 formed so that the conversion pin 1321 is movable in the axial direction, and the conversion pin 1321 extending from the first line 1312 can be rotated about the tool shaft 110 . It is formed with a second line 1313 formed so as to
The housing 131 is
When the ratchet rotor 132 rotates about the tool shaft 110 , it slides with the first lifting protrusion 1342 protruding from one side of the second ratchet 134 and the second ratchet 134 . Conversion module (100), characterized in that the second lifting projection (1314) is formed by raising the first ratchet (133) and coupled.
4. The method of claim 3,
The spring holder 121 is
A second fastening groove 1213 that is recessed into the inner circumferential surface to be fastened with the housing 131 is formed,
The housing 131 is
A conversion protrusion 1315 selectively fastened to the second fastening groove 1213 is formed, and the torque limit unit 120 is activated or deactivated depending on whether the conversion protrusion 1315 is fastened. module 100.
4. The method of claim 3,
The first ratchet 133 and the second ratchet 134 have
Conversion module ( 100 ), characterized in that the tool shaft ( 110 ) fixed to the first ratchet ( 133 ) is reciprocated in the axial direction by forming concave and convex portions engaged with each other on the surfaces facing each other.

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