JP2011005574A - Oil pulse tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact oil pulse tool minimized in the total length of a housing body.SOLUTION: In the oil pulse tool 1, an electric fan 17 is provided inside the housing 6 on the side opposite to a motor from a grip 6a, air taken through an air intake port 15 in the vicinity of the motor and air taken through an air intake port 16 in the vicinity of an oil pulse unit are sucked by the electric fan 17 and are exhausted to the outside through an air exhaust port 14 below the grip 6a. Arrangement of the electric fan 17 below the grip 6a dispenses with the arrangement of a cooling fan on a rotating shaft 3e of the motor 3, shortening the longitudinal length of the tool. Also, the direct connection of an input shaft of the oil pulse unit 4 to the rotating shaft 3e of the motor 3 dispenses with a speed reduction mechanism, lowering the weight and reducing the influence of reaction in driving-in.

Description

  The present invention relates to an oil pulse tool that is rotationally driven by a motor and tightens a fastening member such as a bolt using an intermittent impact force generated by hydraulic pressure.

  As an impact tool for tightening screws, bolts, etc., an oil pulse tool that generates a striking force using hydraulic pressure is known. Since the oil pulse tool does not collide with each other, it has a feature that the operation sound is lower than that of a mechanical impact tool. As such an oil pulse tool, there exists patent document 1, for example, and an electric motor is used as motive power which drives an oil pulse unit. When the trigger switch is pulled to operate the oil pulse tool, driving power is supplied to the motor. When the motor rotates, the rotation is decelerated through the deceleration mechanism and transmitted to the oil pulse mechanism, thereby rotating the anvil.

JP 2003-291074 A

  In the technique of Patent Document 1, the oil pulse mechanism includes an anvil that is substantially rod-shaped and is directed forward of the outer frame, a cylindrical body that is provided substantially coaxially with the anvil radially outward of the anvil, A blade for partitioning the space in the body. A space defined by the anvil and the cylindrical body is filled with oil, and a plurality of oil chambers are defined by the blades. The cylindrical body is drivingly connected to the output shaft of the motor via the speed reduction mechanism, and as the motor rotates at a substantially constant speed, the cylindrical body is at a substantially constant speed that is decelerated from the output shaft of the motor. Rotate. When the cylindrical body is rotating, the oil in the predetermined oil chamber is compressed, and a pressure difference is generated between the oil chambers. Rotating pulse torque is generated in the anvil as the anvil rotates to eliminate this pressure difference.

  When the rotation pulse torque is generated in the anvil, heat is generated by sliding a part of the anvil in contact with each other and a part of the cylindrical body. Further, when the oil moves from the high pressure oil chamber to the low pressure oil chamber, frictional resistance is generated and heat is generated. If the heat generated in the oil pulse mechanism is left unattended, the temperature of the oil rises, and there is a risk that output fluctuation will occur due to the change in the viscosity of the oil. In addition, since the oil expands thermally, there is a possibility that oil leakage from the oil pulse mechanism may be angry, and it is important to take measures against this.

  On the other hand, the striking mechanism of the oil pulse tool uses a hydraulic pressure to generate a striking force. Since a strong striking force is applied to the output shaft at the time of striking with the hydraulic pressure, the reaction may cause the motor rotation to be temporarily locked. In particular, in the case of an oil pulse tool provided with a speed reduction mechanism between the motor and the oil pulse unit, a reaction force is generated at the location where the speed reduction mechanism is held, and the reaction force causes the main body to be greatly displaced. Sexuality sometimes worsened. Accordingly, efforts have been made to reduce this reaction force as much as possible.

  The present invention has been made in view of the above background, and an object thereof is to provide a compact oil pulse tool by shortening the overall length of the body portion of the housing as much as possible.

  Another object of the present invention is to provide an oil pulse tool in which the reaction transmitted to the main body at the time of impact is reduced and the operability is improved.

  Still another object of the present invention is to provide an electric oil pulse tool capable of sufficiently cooling an oil pulse mechanism.

  The characteristics of representative ones of the inventions disclosed in the present application will be described as follows.

  According to one aspect of the present invention, there is provided an oil pulse tool having a motor, an oil pulse unit that is coupled to the motor and generates hydraulic power using a hydraulic pressure, and a housing that accommodates the oil pulse unit. And an electric fan is provided inside the grip part of the housing or on the side opposite to the motor from the grip part of the housing, and a first air intake port is provided near the motor of the housing. The air taken in from the air intake port is sucked and the motor is cooled and then discharged outside the housing. The input shaft of the oil pulse unit is directly connected to the rotation shaft of the motor without passing through the speed reduction mechanism, and is configured such that the rotation speeds of the motor and the input portion of the oil pulse unit are equal. An air passage that spatially connects the electric fan and the motor is formed inside the grip portion of the housing.

  According to another feature of the present invention, the second air intake is provided in the vicinity of the oil pulse unit of the housing, and the electric fan taken after the air taken in from the second air intake flows around the oil pulse unit. To the outside of the housing by the electric fan. The air taken in from the second air intake port flows around the motor after cooling the oil pulse unit, and flows to the electric fan together with the air taken in from the first air intake port. By configuring as described above, it is possible to configure without arranging a cooling fan on the axis of the rotating shaft of the motor.

  According to still another aspect of the present invention, there is provided an oil pulse tool including a motor, an oil pulse unit that is coupled to the motor and generates a striking force using hydraulic pressure, and a housing that accommodates the oil pulse unit. A grip portion is formed, and an electric fan is provided inside the housing and inside the grip portion or on the opposite side of the motor from the grip portion of the housing, and a second air intake port is provided near the oil pulse unit of the housing. The air taken in from the second air intake port was sucked by the electric fan, and the oil pulse unit was cooled and then discharged outside the housing. The input shaft of the oil pulse unit is directly connected to the rotation shaft of the motor without passing through the speed reduction mechanism, and the rotational speeds of the motor and the input portion of the oil pulse unit are configured to be equal.

  According to the first aspect of the present invention, the electric fan is provided inside the housing and in the grip portion or on the side opposite to the motor from the grip portion of the housing, and is taken in from the first air intake port by the electric fan. Since air is sucked and discharged to the outside of the housing, the motor can be effectively cooled without providing a cooling fan on the rotating shaft of the motor.

  According to the invention of claim 2, since the input shaft of the oil pulse unit is directly connected to the rotating shaft of the motor, a speed reduction mechanism becomes unnecessary. Further, since a member for holding the speed reduction mechanism is not required, the weight can be reduced, and the reaction that occurs in the main body at the time of impact can be reduced, and the operability can be improved. In addition, since there is no speed reduction mechanism, the overall length of the housing body can be shortened, miniaturization can be realized, and operability in a narrow space is improved.

  According to the invention of claim 3, since the air passage for spatially connecting the electric fan and the motor is provided inside the grip portion of the housing, the inside of the grip portion of the housing can be effectively used as an air passage. . Furthermore, the trigger control board for the trigger switch provided in the grip part can be cooled.

  According to the invention of claim 4, the second air intake is provided in the vicinity of the oil pulse unit of the housing, and the air taken in from the second air intake flows in the vicinity of the oil pulse unit. The oil pulse unit can also be cooled effectively.

  According to the fifth aspect of the present invention, the air taken in from the second air intake port flows around the motor after cooling the oil pulse unit, and enters the electric fan together with the air taken in from the first air intake port. Since it flows in, both a motor and an oil pulse unit can be cooled using one electric fan.

  According to the invention of claim 6, since no cooling fan is arranged on the axis of the rotation shaft of the motor, the front and rear length of the housing can be shortened, miniaturization can be realized, and operability in a narrow place. Will improve.

  According to the seventh aspect of the present invention, the electric fan is provided inside the housing and in the grip portion or on the opposite side of the motor from the grip portion of the housing, and the heated air around the oil pulse unit is provided by the electric fan. Since suction is performed via the grip portion and discharged to the outside of the housing, the oil pulse unit can be effectively cooled.

  According to the invention of claim 8, since the input shaft of the oil pulse unit is directly connected to the rotating shaft of the motor, the speed reduction mechanism becomes unnecessary. Further, not only the speed reduction mechanism is eliminated, but also a member for holding the speed reduction mechanism is unnecessary, so that the weight can be reduced, the reaction that occurs in the main body at the time of impact can be reduced, and the operability can be improved. Become.

  According to the invention of claim 9, the housing has a body part and a grip part extending downward from the body part. Since the electric fan is accommodated in the grip part, a cooling fan is not provided on the rotating shaft of the motor. Can also effectively cool the motor. In addition, since there is no cooling fan in the body part, the front and rear length of the housing can be shortened, and the operability in a narrow place is improved.

  The above and other objects and novel features of the present invention will become apparent from the following description and drawings.

It is a longitudinal section showing the whole oil pulse tool concerning the example of the present invention. It is sectional drawing of the oil pulse unit 4 of FIG. It is sectional drawing of the AA part of FIG. 2, Comprising: It is sectional drawing which showed the motion of one rotation in the use condition of the oil pulse unit 4 in eight steps. 2 is a right side view showing an appearance of the oil pulse tool 1. FIG. It is a perspective view which shows the external appearance of the oil pulse tool 1, and is the figure seen from the diagonally left front. It is the perspective view of the electric fan 17 single-piece | unit, and is the figure seen from the upper side. 3 is a block diagram illustrating a configuration of a drive control system of a motor 3. FIG. It is a longitudinal section showing the whole oil pulse tool concerning the 2nd example of the present invention.

  Embodiments of the present invention will be described below with reference to the drawings. In the description of the present specification, the vertical and forward / backward directions will be described as the directions shown in FIG. FIG. 1 is a cross-sectional view showing an entire oil pulse tool according to an embodiment of the present invention.

  In FIG. 1, an oil pulse tool 1 uses electric power supplied from a battery pack 2 to drive an oil pulse unit 4 using a motor 3 as a drive source, and a main shaft (anvil) 24 as an output shaft of the oil pulse unit 4. By applying a rotational force and a striking force to the tool, a rotational striking force is directly or intermittently transmitted to a tip tool (not shown) such as a driver bit to perform operations such as screw tightening and bolt tightening. In the present embodiment, the rotating shaft 3e of the motor 3 is directly connected to the input portion of the oil pulse unit 4 without using a speed reduction mechanism. Accordingly, the rotation speed of the motor 3 and the liner 21 of the oil pulse unit 4 rotate in synchronism at the same speed.

  The power supplied by the battery pack 2 is, for example, 14V DC power, and is sent to the motor 3 via an inverter circuit described later. The motor 3 has a stator (stator) 3b having a winding wound around a stator core on the outer peripheral side, a rotor (rotor) 3a having a permanent magnet on the inner peripheral side, and an inverter behind the motor 3 This is a brushless DC motor having a motor substrate 7 on which a circuit is mounted. The rotating shaft 3e is rotatably held by two bearings 10b and 10c, and is accommodated in a cylindrical body portion (a portion that accommodates components arranged on the axis of the rotating shaft of the motor) of the housing 2.

  The housing 6 is formed with a portion extending downward from the body portion at a substantially right angle, and a part thereof serves as a grip portion 6a that is gripped by an operator. A trigger switch 8 is provided in front of the vicinity of the upper portion of the grip portion 6 a, and a voltage that is approximately proportional to the amount by which the trigger switch 8 is pulled is transmitted to the motor 3. The battery pack 2 is detachably attached below the grip 6a, that is, on the side opposite to the motor 3 (on the side opposite to the motor) when viewed from the grip 6a.

  On the extension line (on the axis line) of the rotating shaft of the motor 3 and in the body part of the housing 6, as main components, a motor substrate 7, an oil pulse unit 4 as a striking force generating mechanism, and bearings 10a, 10b. 10c and the inner cover 12 holding the bearing 10b. In this embodiment, there is no speed reduction mechanism or cooling fan as found in a general electric oil pulse tool on the axis of the rotating shaft of the motor 3. As described above, since only the minimum necessary parts for performing the tightening work are arranged on the rotation axis of the motor 3, the front-rear length (full length) of the electric tool can be made extremely short, and the size can be reduced. The operability can be greatly improved.

  The electric fan 17 for cooling the motor 3 is mounted on the side opposite to the motor from the grip 6a of the housing 6 and on the upper side of the control board 9 for mounting the control unit 40 (see FIG. 7). . The electric fan 17 is an electric cooling fan that rotates independently of the motor 3. In the present embodiment, a unit-shaped fan in which a small DC motor and a fan are housed is used. The electric fan 17 is arranged so that its rotating shaft is in the vertical direction, and sucks air from above the vicinity of the rotating shaft and discharges it forward in one circumferential direction. The air sucked by the electric fan 17 is taken in from the first air intake port 15 formed in the outer peripheral portion of the motor 3, and is between the rotor 3a and the stator 3b of the motor 3 and the outer periphery of the stator 3b. After cooling the motor 3 by flowing through the side, it flows in the direction of arrows 19a, 19b, 19c and flows into the electric fan 17. Thereafter, the taken-in air is discharged to the front side of the electric fan 17, and is discharged to the outside from the air discharge port 14 formed in the housing 6 in the direction of the arrow 19d.

  On the other hand, in the oil pulse tool 1 of the present embodiment, the air flow generated by the electric fan 17 is used not only for cooling the motor 3 but also for cooling the oil pulse unit 4. Therefore, a plurality of second air intake ports 16 are provided around the oil pulse unit 4 of the housing 6. The air taken in from the air intake port 16 cools the oil pulse unit 4 by flowing along the outer periphery of the oil pulse unit 4, and then passes through a plurality of axially extending through holes 12 a formed in the inner cover 12. The air flows to the space on the motor 3 side, merges with the air taken in from the air intake port 15, and flows to the electric fan 17 through the internal space of the grip portion 6 a. This is because the heat generated by the oil pulse unit 4 is not large compared to the heat generated by the motor 3, so that the motor 3 can be further cooled by the air that has cooled the oil pulse unit 4.

  In addition, the cooling air passage of the motor 3 portion and the cooling air passage of the oil pulse unit 4 are configured separately, and a passage flowing from the space on the motor 3 side to the grip portion 6a and the space on the oil pulse unit 4 side are gripped. The passages that flow through the portion 6a may be configured separately, and these may be configured to merge within the grip portion 6a. In the case of such a configuration, the inner cover 12 may not have the through hole 12a extending in the axial direction.

  Since the electric fan 17 is provided below the grip portion 6a while minimizing the parts arranged on the rotating shaft 3e of the motor 3 as described above, the motor 3 and the oil pulse unit 4 are effectively cooled while the main body is It becomes possible to reduce the size. Furthermore, since the cooling air passes through the grip portion 6a as indicated by arrows 19a to 19d, the trigger control board 8a for the trigger switch 8 provided in the grip portion 6a can be cooled.

  In the oil pulse unit 4 incorporated in the body portion of the housing 6, a fitting shaft portion 23a (see FIG. 2) protruding rearward is directly connected to the rotating shaft 3e of the motor 3 without a reduction mechanism or the like. As for the fitting shaft part 23a, the cross-sectional shape of the back side is formed in hexagonal shape, and the fitting shaft part 23a is attached to the fitting hole formed in the rotating shaft 3e. The main shaft 24 extending to the front side of the oil pulse unit 4 serves as an output shaft of the oil pulse unit 4, and a mounting hole 24 a is formed at a tip portion thereof. A tip tool (not shown) is mounted in the mounting hole 24a. When the trigger switch 8 is pulled to start the motor 3, the rotational force of the motor 3 is transmitted to the oil pulse unit 4, and the liner 21 of the oil pulse unit 4 rotates at the same speed as the rotational speed of the motor 3.

  The oil pulse unit 4 is filled with oil, and when the main shaft 24 is not loaded, or when the load is small, the main shaft 24 is almost free from rotation of the motor 3 only by the resistance of the oil. Rotate synchronously. When a heavy load is applied to the main shaft 24, the rotation of the main shaft 24 stops, and only the liner 21 on the outer peripheral side of the oil pulse unit 4 continues to rotate, and the oil pressure is at a position where one place of oil is sealed per rotation. It rapidly rises, and a large tightening torque (blowing force) acts on the main shaft 24 to rotate the main shaft 24 with a large force. Thereafter, the same impact operation is repeated several times, and the striking force is intermittently and repeatedly transmitted to the main shaft 24 until the fastening target is tightened with the set torque.

  FIG. 2 is a cross-sectional view of the oil pulse unit 4 of FIG. The oil pulse unit 4 mainly includes a drive part (21, 23, 32) that rotates in synchronization with the output shaft 3e of the motor 3 and an output part (24, 25a, 25b, 29) to which the tip tool is attached. It is mainly composed of two. A drive portion that rotates in synchronization with the output shaft 3e of the motor 3 extends forward on the outer peripheral side of the liner plate 23 having a fitting shaft portion 23a connected to a hexagonal hole formed in the output shaft 3e. A substantially cylindrical liner 21 to be fixed is included. The output portion is configured to include a main shaft 24 and blades 25 a and 25 b attached to the main shaft 24 via the spring 5.

  The main shaft 24 is held so as to be able to rotate in the liner 21, and the space between the liner 21 and the main shaft 24 is filled with hydraulic oil (oil) for generating torque. The space filled with hydraulic oil is sealed by a liner plate 23 attached to the liner 21. Between the liner 21 and the main shaft 24 and between the liner 21 and the liner plate 23, O-rings 30 and 31 are provided for ensuring airtightness between them. The liner 21 has a relief valve 22 for releasing the oil pressure from the high-pressure chamber to the low-pressure chamber, and can control the maximum pressure of the generated oil and adjust the tightening torque.

  The O-ring 30 seals between the main shaft 24 and the liner 21. The O-ring 31 is provided in an annular groove formed on the outer periphery of the liner plate 23 and seals between the liner 21 and the liner plate 23. At the front end of the main shaft 24, a hexagon hole 24a for inserting a tip tool is formed. The hexagonal hole 24a has a hexagonal cross section in a plane perpendicular to the axial direction (front-rear direction). Blades 25 a and 25 b are fitted and inserted into two grooves through springs 29 on the outer peripheral portion on the rear side of the main shaft 24, and the blades 25 a and 25 b are radially arranged by the springs 29 so as to contact the inner surface of the liner 21. Be energized.

  FIG. 3 is a cross-sectional view taken along the line AA in FIG. 2, and is a cross-sectional view illustrating the movement of one rotation in the use state of the oil pulse unit 4 in eight stages. As shown in FIGS. 3 (1) and 3 (2), the outer peripheral surface of the main shaft 24 between the blades 25a and 25b is provided with two convex seal surfaces 26a and 26a that are axially extending. Convex seal surfaces 27a and 27b and convex portions 28a and 28b are formed on the inner peripheral surface of the liner 21. With the above configuration, a liner chamber that forms approximately four cross-sectional areas is formed inside the liner 21.

  When the seating surface of the tightening bolt is seated when the oil pulse tool 1 is tightened, the main shaft 24 is loaded, the main shaft 24 and the blades 25a and 25b are almost stopped, and only the liner 21 continues to rotate. Along with the rotation of the liner 21 due to the rotation of the motor 3, an impact pulse is generated once per rotation. When this shock pulse is generated, the oil pulse tool 1 has a convex seal formed on the inner peripheral surface of the liner 21. The convex seal surface 26 a formed on the outer surface of the main shaft 24 is in contact with the surface 27 a. At the same time, the convex seal surface 27 b formed on the inner peripheral surface of the liner 21 and the convex seal surface 26 a formed on the outer peripheral surface of the main shaft 24 come into contact. As described above, the pair of convex seal surfaces formed on the inner peripheral surface of the liner 21 and the pair of convex seal surfaces formed on the outer peripheral surface of the main shaft 24 are in contact with each other. It is partitioned into a chamber H and two low pressure chambers L. Then, the main shaft 24 rotates to tighten the tightening bolt due to the pressure difference between the high pressure chamber H and the low pressure chamber L.

  Next, the operation procedure of the oil pulse unit 4 will be described with reference to the flow of FIGS. 3 (1) to 3 (8) are views showing a state in which the liner 21 makes one rotation at a relative angle with respect to the main shaft 24. FIG. First, the motor 3 is rotated by pulling the trigger 8, and the liner 21 is rotated in synchronization therewith. As described above, when no load is applied to the main shaft 24 or when the load is small, the main shaft 24 rotates almost in synchronization with the rotation of the motor 3 only by the resistance of oil. When a strong load is applied to the main shaft 24, the rotation of the main shaft 24 directly connected thereto stops and only the outer liner 21 continues to rotate.

  FIG. 3 (1) is a diagram showing a positional relationship when a striking force due to an impact pulse is generated on the main shaft 24. The position shown in (1) is a position for sealing oil at one place per rotation. Here, the convex seal surfaces 27a and 26a, the seal surface 27b and the seal surface 26a, the blade 25a and the convex portion 28a, and the blade 25b and the convex portion 28b are in contact with each other in the entire axial direction of the main shaft 24, respectively. As a result, the inner space of the liner 21 is divided into four chambers of two high-pressure chambers and two low-pressure chambers.

  Here, the high pressure and the low pressure are pressures of oil existing inside. Further, when the liner 21 is rotated by the rotation of the motor 3, the volume of the high pressure chamber decreases, so that the oil is compressed and a high pressure is instantaneously generated. This high pressure pushes the blade 5 toward the low pressure chamber. As a result, a strong torque is generated on the main shaft 24 by momentarily acting through the upper and lower blades 25a and 25b. By forming this high-pressure chamber, a strong striking force that rotates the blades 25a, 25b in the clockwise direction in the drawing acts. The position shown in FIG. 3A is referred to as “blow position” in this specification.

  FIG. 3B shows a state where the liner 21 is rotated 45 degrees from the striking position. After passing the striking position shown in (1), the convex sealing surfaces 27a and 26a, the convex sealing surface 27b and the sealing surface 26a, the blade 25a and the convex portion 28a, and the blade 25b and the convex portion 28b are in contact with each other. Is released, the space partitioned into the four chambers inside the liner 21 is released, and oil flows into the mutual space, so that no torque is generated, and the liner 21 further rotates as the motor 3 rotates.

  FIG. 3 (3) shows a state in which the liner 21 has rotated 90 degrees from the striking position. In this state, since the blades 25a and 25b contact the convex seal surfaces 27a and 27b and retreat to the inner side in the radial direction to the position where they do not protrude from the main shaft 24, no torque is generated without being affected by the oil pressure. The liner 21 rotates as it is.

  FIG. 3 (4) shows a state in which the liner 21 has rotated 135 degrees from the striking position. In this state, the inner space of the liner 21 communicates and no oil pressure change occurs, so that no rotational torque is generated on the main shaft.

  FIG. 3 (5) shows a state in which the liner 21 has rotated 180 degrees from the striking position. At this position, the convex seal surfaces 27b and 26a, and the convex seal surface 27b and the seal surface 26a approach, but do not contact. This is because the convex seal surfaces 26a and 26a formed on the main shaft 24 are not in a symmetrical position with respect to the axis of the main shaft. Similarly, the convex sealing surfaces 27a and 27b formed on the inner periphery of the liner 21 are not in a symmetrical position with respect to the axis of the main shaft. Therefore, torque is hardly generated at this position because it is hardly affected by oil. The generated torque is not zero because the oil filled inside is viscous, and when the convex seal surfaces 27b and 26a or the convex seal surfaces 27a and 26a face each other, Since a high pressure chamber is formed, a slight rotational torque is generated unlike (2) to (4) and (6) to (8).

  The states of FIGS. 3 (6) to (8) are almost the same as (2) to (4), and no torque is generated in these states. Further rotation from the state of (8) returns to the state of FIG. 3 (1), the convex sealing surfaces 27a and 26a, the sealing surface 27b and the sealing surface 26a, the blade 25a and the convex portion 28a, and the blade 25b. Since the convex portions 28b are in contact with each other in the entire axial direction of the main shaft 24, the inner space of the liner 21 is partitioned into four chambers of two high-pressure chambers and two low-pressure chambers. Occurs.

  When a strong impact rotation torque is generated in the main shaft 24, the reaction force is generated in the rotor 3 a of the motor 3 via the liner 21 and the liner plate 23. As shown in FIG. 1, since the oil pulse unit 4 and the motor 3 are directly coupled, and the rotor 3a is not restrained by the bearing 10 in the rotational direction, the reaction force generated in the rotor 3a is not transmitted to the housing 6, The reaction force is not transmitted to the worker. Therefore, it becomes possible to provide good operability to the operator.

  FIG. 4 is a right side view showing the appearance of the oil pulse tool 1. A plurality of air intakes (first air intakes) 15 are formed on the rear side of the housing 6 and on the outer peripheral portion of the portion that houses the motor 3. A plurality of air intakes (second air intakes) 16 are also formed on the front side of the housing 6 and in the outer peripheral portion near the front of the oil pulse unit. The length below the grip portion 6a of the housing 6, that is, the non-motor side of the housing 6 is longer in the vertical direction than the conventional oil pulse tool. However, an adverse effect on actual work due to an increase in the length L2 below the grip portion 6a is hardly a problem. In the present application, the effect of shortening the length L1 of the main body is extremely large.

FIG. 5 is a perspective view showing the external appearance of the oil pulse tool 1, as viewed from the left front side.
A plurality of air discharge ports 14 are formed near the upper side of the battery pack 2 below the grip portion 6 a of the housing 6. Since the air exhaust port 14 is configured to be exhausted forward from the housing 2, the heated exhaust does not directly hit the worker who is working, and the worker is not uncomfortable. Further, since the position where the air discharge port 14 is provided is provided at a location sufficiently away from the main shaft 24, the work by the tip tool is not affected. In the present embodiment, the air discharge port 14 is disposed below and on the front side of the grip portion 6a of the housing 6. However, the present invention is not limited to this position. ).

  FIG. 6 is a perspective view of the electric fan 17 alone, and shows a view from above. The electric fan 17 is provided with a suction port 17a for sucking air in the axial direction, and houses a rotating fan and a fan housing 17b for guiding the sucked and discharged air in a desired direction, and the air in one direction. This is a general-purpose blower fan having a discharge port 17c for discharging. Two screw holes 17d are formed in the fan housing 17b, and the electric fan 17 is fixed to the inner wall of the housing 6 by screws (not shown). The method for fixing the electric fan 17 to the housing 6 is arbitrary. The electric fan 17 may be clamped by the divided housing 6 without using a screw, or may be fixed to the housing 6 with double-sided tape or the like. May be. In the case of using a double-sided tape, if an elastic material is used as a base, a vibration control function for reducing vibration transmitted to the electric fan 17 can be achieved together with an adhesive function.

  Next, the configuration and operation of the drive control system of the motor 3 will be described with reference to FIG. In the present embodiment, the motor 3 is constituted by a three-phase brushless DC motor. This brushless DC motor is a so-called inner rotor type, and includes a rotor (rotor) 3a including a plurality of sets (two sets in this embodiment) of permanent magnets (magnets) including N poles and S poles. In order to detect the rotational position of the rotor 3a, a stator 3b composed of three-phase stator windings U, V, and W connected in a star connection is arranged at predetermined intervals in the circumferential direction, for example, at an angle of 60 °. The three rotational position detecting elements (Hall elements) 42 are provided. Based on the position detection signals from these rotational position detection elements 42, the energization direction and time to the stator windings U, V, W are controlled, and the motor 3 rotates. The rotational position detection element 42 is provided at a position facing the magnet of the rotor 3 a on the motor substrate 7.

  The electronic elements mounted on the motor substrate 7 include an inverter circuit 47 mainly composed of six switching elements Q1 to Q6 such as FETs (Field Effect Transistors) connected in a three-phase bridge format. The gates of the six switching elements Q1 to Q6 that are bridge-connected are connected to the control signal output circuit 46 in the control unit 40 mounted on the control board 9, and the drains of the six switching elements Q1 to Q6. Alternatively, each source is connected to the stator windings U, V, and W that are star-connected. As a result, the six switching elements Q1 to Q6 perform a switching operation by the switching element drive signals (drive signals such as H4, H5, and H6) input from the control signal output circuit 46, and are applied to the inverter circuit 47. Electric power is supplied to the stator windings U, V, and W with the DC voltage of the battery pack 2 as three-phase (U-phase, V-phase, and W-phase) voltages Vu, Vv, and Vw.

  Of the switching element drive signals (three-phase signals) for driving the gates of the six switching elements Q1 to Q6, the three negative power supply side switching elements Q4, Q5, Q6 are converted into pulse width modulation signals (PWM signals) H4, By changing the pulse width (duty ratio) of the PWM signal based on the detection signal of the operation amount (stroke) of the trigger switch 8 by the calculation unit 41 supplied as H5 and H6 and mounted on the control board 9 The power supply amount to the motor 3 is adjusted, and the start / stop of the motor 3 and the rotation speed are controlled. When rotating the motor 3, the calculation unit 41 outputs a drive signal to the fan rotation control unit 44 to rotate the electric fan 17. Although not shown, the electric fan 17 can use electric power (wiring diagram not shown) supplied from the battery pack 2. When the trigger switch 8 is opened and the motor 3 is stopped, the calculation unit 41 outputs a stop signal to the fan rotation control unit 44 to stop the electric fan 17.

  It should be noted that the timing of stopping the electric fan 17 may be synchronized with the motor 3, or may be configured to be asynchronous and stopped after a certain time after the motor 3 stops rotating, or a temperature sensor. The rotation and stop of the electric fan 17 may be controlled according to the temperature of the inverter circuit 47 measured by 52.

  Here, the PWM signal is supplied to any one of the positive power supply side switching elements Q1 to Q3 or the negative power supply side switching elements Q4 to Q6 of the inverter circuit 47, and the switching elements Q1 to Q3 or the switching elements Q4 to Q6 are switched at high speed. As a result, the electric power supplied to the stator windings U, V, W from the DC power source of the battery pack 2 is controlled. In this embodiment, since the PWM signal is supplied to the negative power supply side switching elements Q4 to Q6, the electric power supplied to each stator winding U, V, W is controlled by controlling the pulse width of the PWM signal. The rotational speed of the motor 3 can be controlled by adjusting.

  The oil pulse tool 1 is provided with a forward / reverse switching lever 51 for switching the rotational direction of the motor 3, and the rotational direction setting circuit 50 switches the rotational direction of the motor each time a change in the forward / reverse switching lever 51 is detected. Then, the control signal is transmitted to the calculation unit 41. Although not shown, the calculation unit 41 is a central processing unit (CPU) for outputting a drive signal based on the processing program and data, a ROM for storing the processing program and control data, and for temporarily storing data. RAM, a timer, and the like.

  The control signal output circuit 46 forms a drive signal for alternately switching predetermined switching elements Q1 to Q6 based on the output signals of the rotation direction setting circuit 50 and the rotor position detection circuit 43, and controls the drive signal. The signal is output to the signal output circuit 46. As a result, the predetermined windings of the stator windings U, V, and W are alternately energized to rotate the rotor 3a in the set rotation direction. In this case, the drive signal applied to the negative power supply side switching elements Q4 to Q6 of the motor substrate 7 is output as a PWM modulation signal based on the output control signal of the applied voltage setting circuit 49. The current value supplied to the motor 3 is measured by the current detection circuit 48, and the value is fed back to the calculation unit 41 so as to be adjusted to the set driving power. The PWM signal may be applied to the positive power supply side switching elements Q1 to Q3.

  The inverter circuit 47 is provided with a temperature sensor 52 that measures the temperature of the switching element 21, and the temperature rise measuring circuit 45 always measures the temperature of the switching element 21 or its surroundings and outputs the value to the calculation unit 41. . When the temperature of the switching element 21 becomes abnormally high, the calculation unit 41 stops the motor 3 to protect the inverter circuit 47 and the motor 3. The calculation unit 41 may send a signal to the fan rotation control unit 44 to increase the rotation speed of the electric fan 17 when the temperature of the switching element 21 rises above a preset reference value. The speed at which the electric fan 17 is rotated may be controlled not only in one step, but also in two steps of low speed / high speed, or continuously variable.

  As described above, in this embodiment, the speed reduction mechanism is not required by coupling the motor for generating power and the liner of the oil pulse unit so that the rotation speed is equal, and accordingly, there is a place where the speed reduction mechanism is held. As a result, it becomes difficult to cause a reaction in the main body at the time of hitting, and the operability can be improved. Further, since there is no speed reduction mechanism, it is possible to shorten the overall length (front-rear length) of the main body, to achieve downsizing, and to improve the operability in a narrow place. Furthermore, since the electric fan is separately provided for cooling the switching element, the motor, and the oil pulse unit, it is possible to reliably perform the cooling.

  FIG. 8 is a sectional view showing the entire oil pulse tool 1a according to the second embodiment of the present invention. In the second embodiment, the reaction transmitted to the main body at the time of striking is made small at the expense of shortening the overall length (front-rear length) of the oil pulse tool 1a. In addition, the same referential mark is attached | subjected to the part of the same structure as the oil pulse tool 1 which concerns on 1st Example shown in FIG. 1, and description is not repeated.

  What is characteristic in the second embodiment is that a cooling fan 57 is provided on the rotating shaft 3e of the motor 3 instead of the electric fan 17 of FIG. A shaft member 61 is provided on the rotating shaft 3e of the motor 3, and the cooling fan 57 is fixed to the rotating shaft 3e through the shaft member 61 so as not to rotate. A mounting hole 61 d having a hexagonal cross section is formed at the tip of the shaft member 61. The cooling fan 57 is a centrifugal fan that rotates in synchronization with the rotor 3a. When the cooling fan 57 rotates, outside air is taken in from the first air intake port 15, and the air that has cooled the motor substrate 7 and the motor 3 flows into the housing chamber 63 of the cooling fan 57. 2 is discharged to the outside through a plurality of air discharge ports 66 formed on the side of the second.

  Although not shown in FIG. 8, a second air intake (not shown) is provided in the portion of the housing 2 in the vicinity of the oil pulse unit 4, and air is also supplied from the oil pulse unit 4 side by the cooling fan 57. Is sucked and discharged from the air discharge port 66 to the outside. At this time, a plurality of through holes (see FIG. 1) are formed in the inner cover 62 in the same manner as the inner cover 12 of FIG. 1 so that air flows from the space in which the oil pulse unit 4 of the housing 2 is accommodated to the accommodating chamber 63 of the cooling fan 57. (Not shown). In FIG. 8, the plate 67 and the screw 68 for fixing the bearing 10 b to the inner cover 62 from the rear side are located at the longitudinal cross-sectional position, so that a through hole is not drawn, but there are a plurality of circumferential directions. A through hole is formed.

  The cooling fan 57 is made of metal. By configuring the cooling fan 57 with metal, it becomes possible to increase the outer diameter of the cooling fan 57. Therefore, when the striking force is applied to the main shaft 24, the inertial force is effectively increased without increasing the overall weight. It becomes possible to enlarge. As a result, a large tightening torque can be generated without increasing the size of the motor 3. Further, since the speed reduction mechanism is not used, the increase in the total length can be minimized.

  As mentioned above, although demonstrated based on the Example which shows this invention, this invention is not limited to the above-mentioned Example, A various change is possible within the range which does not deviate from the meaning. For example, although the electric fan 17 is provided below the grip portion 6a of the housing 6 in the first embodiment, it may be provided inside the grip portion 6a. Further, in the above-described embodiment, the inside of the grip portion 6a is used as an air passage, but does not form a wall for guiding air, but forms an air guiding path, a current plate or the like. You may form so that cooling air may flow without resistance.

  Further, the switching element 18 for further shortening the front-rear length of the housing 6 is not mounted on the motor substrate 7 but is mounted on the control substrate 9, or another substrate separated from the motor 3. You may make it mount in. With such a configuration, the front-rear length of the housing 6 can be further shortened by the amount of space required for mounting the switching element 18 of the motor substrate 7.

DESCRIPTION OF SYMBOLS 1, 1a Oil pulse tool 2 Battery pack 3 Motor 3a (Motor) stator 3b (Motor) rotor 3e (Motor) rotating shaft 4 Oil pulse unit 5 Spring 6 Housing 6a (Housing) grip part 7 For motor Board 8 Trigger switch 9 Control board 10a, 10b, 10c Bearing
DESCRIPTION OF SYMBOLS 11 Sleeve 12 Inner cover 12a Through hole 13 of (inner cover) Case 14 Air exhaust port 15 (First) Air intake port 16 (Second) Air intake port 17 Electric fan 17a Suction port 17b Fan housing 17c Discharge port 17d Screw hole 18 Switching element 21 Liner 22 Relief valve 23 Liner plate 24 Main shaft 24a (Main shaft) mounting holes 25a and 25b Blades 26a and 26b Convex seal surfaces 27a and 27b Convex seal surfaces 28a and 28b Convex part 29 Spring 30, 31 O-ring 32 Liner cover 41 Calculation unit 42 Rotation position detection element 43 Rotor position detection circuit 44 Fan rotation control unit 45 Temperature rise measurement circuit 46 Control signal output circuit 47 Inverter circuit 48 Current detection circuit 49 Applied voltage setting circuit 50 rotation Direction setting circuit 51 forward-reverse switching lever 52 temperature sensor 53 radiator 57 cooling fan
61 Shaft member 61d (shaft member) mounting hole 62 Inner cover 63 Storage chamber 66 Air outlet 67 Plate 68 Screw

Claims (9)

An oil pulse tool having a motor, an oil pulse unit that is connected to the motor and generates a striking force using hydraulic pressure, and a housing that accommodates these units,
A grip portion is formed on the housing,
An electric fan is provided inside the grip portion of the housing, or on the opposite side of the motor from the grip portion of the housing,
Providing a first air intake near the motor of the housing;
An oil pulse tool characterized in that air taken in from a first air intake port is sucked by the electric fan, and the motor is cooled and then discharged outside the housing.   2. The oil pulse tool according to claim 1, wherein an input shaft of the oil pulse unit is directly connected to a rotation shaft of the motor, and rotation speeds of the input portion of the motor and the oil pulse unit are equal.   The oil pulse tool according to claim 1 or 2, wherein an air passage for spatially connecting the electric fan and the motor is provided in a grip portion of the housing. A second air intake is provided near the oil pulse unit of the housing;
The air taken in from the second air intake port reaches the electric fan after flowing around the oil pulse unit, and is discharged to the outside of the housing by the electric fan. The oil pulse tool as described in any one of -3.   The air taken in from the second air intake port flows around the motor after cooling the oil pulse unit, and flows to the electric fan together with the air taken in from the first air intake port. The oil pulse tool according to any one of claims 1 to 4.   The oil pulse tool according to any one of claims 1 to 5, wherein a cooling fan is not disposed on the axis of the rotation shaft of the motor. An oil pulse tool having a motor, an oil pulse unit that is connected to the motor and generates a striking force using hydraulic pressure, and a housing that accommodates these units,
A grip portion is formed on the housing,
An electric fan is provided inside the housing, in the grip portion, or on the side opposite to the motor than the grip portion of the housing,
A second air intake is provided near the oil pulse unit of the housing;
An oil pulse tool, wherein the air taken in from the second air intake port is sucked by the electric fan, and the oil pulse unit is cooled and then discharged outside the housing.   The oil pulse tool according to claim 7, wherein an input shaft of the oil pulse unit is directly connected to a rotation shaft of the motor, and rotation speeds of the motor and the input portion of the oil pulse unit are equal. A motor,
An oil pulse unit connected to the motor;
An oil pulse tool having a housing for housing the motor and the oil pulse unit,
The housing has a body part that houses the motor and the oil pulse unit, and a grip part that extends downward from the body part,
An oil pulse tool characterized in that an electric fan is accommodated in the grip portion.

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