JP4421193B2 - Tightening tool - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a tightening tool such as an impact wrench, an impact driver, a torque wrench, etc., in which rotation of a motor is transmitted to a main shaft via an impact force generating means.
[0002]
[Prior art]
With a tightening tool for tightening screws (bolts, nuts, etc.) with a large tightening torque against a member to be tightened (for example, a steel plate, etc.), the rotational torque of the motor is transmitted to the main shaft via impact force generating means. Is done. Generally, in this type of tightening tool, the tightening torque of screws is determined by the number and frequency of impact forces generated from the impact force generating means. Therefore, in order to make the tightening torque of the screws constant for each work, the motor is automatically stopped after a predetermined time after the first impact force is generated, or the number of times the impact force is generated becomes the set value. A tightening tool has been developed that automatically stops the motor when it hits (for example, Patent Document 1).
[0003]
[Patent Document 1]
JP 2000-210877 A
[0004]
[Problems to be solved by the invention]
By the way, in the tightening operation using the above-described tightening tool, when the type (for example, material (hardness)) of the member to be tightened changes, the tightening torque of the screws also changes. That is, even if the same screws are tightened under the same motor stop conditions (for example, the number of times of impact force generation is constant), the tightening torque of the screws changes if the type of member to be tightened is different. The proper tightening torque of the screws is usually determined by the type of the screws regardless of the type of the member to be tightened, and the proper tightening torque is the same value if the screws are the same. Therefore, in order to set the tightening torque of the screws to an appropriate value when the same screws are tightened to different tightening members, the motor stop condition must be changed according to the type of the tightening member. In the conventional tightening tool, since the change of the motor stop condition is performed by the worker, if the worker mistakenly changes the motor stop condition, the screws cannot be tightened with an appropriate tightening torque.
[0005]
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to fasten screws to different tightening members with an appropriate tightening torque without changing motor stop conditions. Provide tightening tools.
[0006]
[Means, actions and effects for solving the problems]
In order to solve the above-mentioned problems, the tightening tool according to the first invention of the present application is a tightening tool for tightening screws so as to have tightening torques set for a plurality of types of members to be tightened. When the load acting on the main shaft is below a predetermined value, the rotational torque from the motor is directly transmitted to the main shaft. An impact force generating means for rotating the main shaft and generating an impact force when the load acting on the main shaft exceeds a predetermined value to rotate the main shaft; and a rotation angle detecting means for detecting a change in the rotation angle of the main shaft and its rotation direction; And means for storing a plurality of automatic stop conditions for automatically stopping the motor.
Then, the motor control means of this tightening tool is the "cumulative rotation angle amount in the screw tightening direction of the main shaft" obtained from the rotation angle change of the main shaft detected by the rotation angle detecting means and the rotation direction after the screws are seated. When “Amount of rotation angle per impact force of the spindle” One of And selecting one automatic stop condition from a plurality of automatic stop conditions stored in the automatic stop condition storage means, and stopping the motor when the selected automatic stop condition is satisfied. And
[0007]
In this tightening tool, the type of the member to be tightened that is performing the tightening operation is specified based on the movement state of the main shaft after seating detected by the rotation angle detecting means. That is, when the type of the tightening member is different, the movement state of the main shaft after the seating is different, and the type of the tightening member performing the tightening operation is specified by this difference. If the type of the member to be tightened can be specified, the automatic motor stop condition corresponding to the type can be selected. The motor control means of the tightening tool stops the motor when the automatic stop condition thus selected is satisfied. Therefore, even if the operator does not change the motor stop condition, the screws can be tightened with different tightening members with an appropriate tightening torque.
[0008]
Here, the difference in the motion state of the main shaft after seating due to the difference in the types of screws described above will be specifically described with reference to FIGS. 15 to 17. FIG. 15 shows changes in the rotation angle of the main shaft when a machine screw is fastened to a hard member such as iron (hereinafter referred to as a hard joint material) and the rotation angle of the main shaft per impact (one impact force) after sitting. An example of the transition is also shown. FIG. 16 shows changes in the cumulative rotation angle of the main shaft when a mechanical screw is tightened on a soft member such as wood (hereinafter referred to as a soft joint material), and the rotation angle of the main shaft per impact (one impact force) after sitting. An example of the transition is also shown. FIG. 17 shows an example of transition of the cumulative rotation angle of the main shaft after seating for each of the hard joint material and the soft joint material.
As apparent from FIGS. 15 to 17, the transition of the cumulative rotation angle of the main shaft before sitting is substantially the same, but the transition of the cumulative rotation angle of the main shaft after sitting is greatly different. With hard joint materials, the rotation angle of the main shaft per impact is small, and the screws hardly rotate after sitting. On the other hand, with the soft joint material, the rotation angle of the main shaft per impact is large, and the screws rotate after sitting. Therefore, for example, the rotation angle of the main shaft detected by the rotation angle detection means and the rotation direction of the main shaft after the seating (and / or the rotation angle of the main shaft per impact) are obtained from the rotation direction, and this value is used for tightening. It is possible to determine whether the attachment member is a hard joint material or a soft joint material. Therefore, if the hard joint material is used, the motor is stopped under the stop condition for the hard joint material, and if the soft joint material is used, the motor may be stopped under the stop condition for the soft joint material.
[0009]
Therefore, the motor control means (1) cumulative rotation in the screw tightening direction of the main shaft within a predetermined time set after the screws are seated based on the rotation angle change of the main shaft detected by the rotation angle detecting device and its rotation direction. The angle amount is calculated, (2) the type of the tightening member is determined from the calculated cumulative rotation angle amount, and (3) the automatic stop condition corresponding to the determined type of the tightening member is satisfied. Sometimes it is preferably programmed to stop the motor.
Note that the type of the member to be tightened (for example, a hard joint material or a soft joint material) can be determined by various indices other than the above-described cumulative rotation angle of the main shaft and the rotation angle of the main shaft per impact. For example, the fluctuation rate of the rotation angle of the spindle per impact can also be used.
[0010]
The automatic stop condition may be a motor driving time after the screws are seated, or may be the number of times the impact force is generated from the impact force generating means after the screws are seated.
According to such a configuration, the motor is driven until a predetermined time elapses after the screws are seated or until a predetermined number of impact forces are generated, and the screws can be tightened with an appropriate tightening torque.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
In a tightening tool according to an embodiment embodying the present invention, rotation of a motor is transmitted to a main shaft via an impact force generation mechanism, and screws are tightened by rotating the main shaft. The tightening tool includes a rotary encoder that detects a change in the rotation angle of the main shaft and its rotation direction. The rotary encoder is connected to motor control means (for example, a microcomputer), and a detection signal of the rotary encoder is input to the motor control means.
The motor control means stores the amount of change in the rotation angle of the main shaft detected by the rotary encoder and its rotation direction at a preset cycle. (1) When a change in the rotation angle of the main shaft occurs, the rotation angle from the time point that has been traced back from the rotation angle change by the first set time from the stored rotation angle change amount and the rotation direction of the main shaft. The amount of change in the rotation angle in the screw tightening direction of the spindle until the time when the change occurs is calculated. (2) When the calculated amount of change in rotation angle is within the first set value, the change from the change in rotation angle to the second set time. (3) When the calculated absolute value of the rotational angle change amount is equal to or greater than the second set value, the rotational angle change of (1) above is calculated. It is determined that the occurrence of impact force is the beginning of the generation of impact force.
The motor control means further determines that the rotation angle change amount in the screw tightening direction of the main shaft until the third set time elapses after the rotation angle change of the main shaft determined to be at the start of impact force generation is less than or equal to the third set value. Then, it is determined that the screws are seated on the fastened member.
If it is determined that the screws are seated, then the motor control means calculates the cumulative rotation angle of the main shaft during the set time after the seating. Then, when the calculated cumulative rotation angle exceeds the fourth set value, the motor is further driven for a predetermined time, and when the calculated cumulative rotation angle is within the fourth set value, the motor is stopped.
[0012]
【Example】
Next, an angle soft impact wrench according to an embodiment embodying the present invention will be described. FIG. 1 shows a partial sectional side view of an angle soft impact wrench. In the angle soft impact wrench 1 shown in FIG. 1, a motor M (not shown in FIG. 1, but shown in FIG. 6) as a drive source is accommodated and fixed in a housing 3. The planetary gear mechanism 18 is connected to the output shaft 20 of the motor M, and the oil unit 12 is connected to the output shaft 16 of the planetary gear mechanism 18 via the buffer mechanism 14.
The oil unit 12 is a known device that instantaneously generates a large impact force (oil pulse) on the output shaft 8 by using the pressure of the oil accommodated therein. The oil pulse generated in the oil unit 12 is adjusted so as to obtain a predetermined impact force by adjusting the maximum pressure value of the oil accommodated therein. The buffer mechanism 14 is disclosed in a publicly known mechanism (for example, Japanese Utility Model Laid-Open No. 7-31281) for preventing an impact when an oil pulse is generated by the oil unit 10 from being directly transmitted to the planetary gear mechanism 16 side. Mechanism).
The output shaft 8 of the oil unit 12 is supported by a bearing device 10 which will be described in detail later, and a bevel gear 6 is connected to the tip of the shaft. The bevel gear 6 meshes with a bevel gear 4 provided at one end of a spindle 2 that is supported orthogonally to the output shaft 8. The other end of the spindle 2 is attached with a socket (not shown) that engages with a head such as a bolt or a nut.
Therefore, when the motor M rotates in the angle soft impact wrench 1, the rotation is decelerated by the planetary gear mechanism 16 and transmitted to the oil unit 12. The oil unit 12 transmits the rotation transmitted from the motor 22 to the spindle 2 as it is without generating an oil pulse because the load on the spindle 2 is low at the initial stage where tightening of nuts is started. For this reason, the spindle 2 rotates continuously, and the screws are continuously tightened accordingly. On the other hand, when the screws are tightened to increase the load on the spindle 2 (output shaft 8), an oil pulse is generated from the oil unit 12, and the screws are tightened by the impact force.
[0013]
Next, a bearing device 10 (corresponding to a rotary encoder in the claims) that rotatably supports the output shaft 8 of the oil unit 12 that operates as described above will be described with reference to FIGS. Here, FIG. 2 is a sectional view showing the structure of the bearing device, FIG. 3 is a diagram schematically showing the positional relationship between the magnet incorporated in the bearing device and the rotation angle detection sensor, and FIGS. 4 and 5 are outputs. It is a figure which shows the state of the detection signal output from two rotation angle detection sensors, respectively, when the axis | shaft 8 carries out normal rotation or reverse rotation.
As shown in FIG. 2, the bearing device 10 includes an inner cylinder 30 and an outer cylinder 34 that rotatably supports the inner cylinder 30. The inner cylinder 30 is formed with an insertion hole having substantially the same diameter as the outer diameter of the output shaft 8 of the oil unit 12 (slightly smaller than the outer diameter of the output shaft 8). The output shaft 8 of the oil unit 12 is press-fitted into the insertion hole from the right end side of the drawing, whereby the inner cylinder 30 is fixed to the output shaft 8. Therefore, when the output shaft 8 rotates, the inner cylinder 30 rotates together with the output shaft 8.
A cylindrical magnet attachment member 40 is fixed to the right end of the inner cylinder 30 in the drawing. A plurality of magnets 42 (shown by 42a, 42b, 42c... In FIG. 3) are arranged at equal intervals on the outer periphery of the magnet mounting member 40. As shown in FIG. 3, the magnet 42 includes magnets 42 a, 42 c... Arranged so that the S pole is on the outer peripheral side, and magnets 42 b... Arranged so that the N pole is on the outer peripheral side. The magnets 42a, 42c... With the S pole on the outer peripheral side and the magnets 42b with the N pole on the outer peripheral side are alternately arranged. Note that the center angle between adjacent magnets (for example, the angle formed by the center of the magnet 42a, the center of the magnet 42b, and the rotation center of the inner cylinder 30) is the same angle at α ° as shown in FIG.
[0014]
The outer cylinder 34 is a cylindrical member having an inner diameter larger than that of the inner cylinder 30 as shown in FIG. A ball 32 is interposed between the inner cylinder 30 and the outer cylinder 34, and the inner cylinder 30 is assembled so as to be rotatable with respect to the outer cylinder 34. Therefore, when the outer cylinder 34 is accommodated and fixed in the housing 3, the inner cylinder 30 (that is, the output shaft 8) is rotatably supported with respect to the outer cylinder 34 (that is, the housing 3).
A cylindrical sensor attachment member 36 is fixed to the right end of the outer cylinder 34 in the drawing. Rotation angle detection sensors 38a and 38b are disposed on the inner wall surface of the sensor mounting member 36 at positions facing the magnet 42 (see FIG. 3). The rotation angle detection sensors 38a and 38b are latch type Hall ICs that detect a change in the magnetic field and switch the state of the detection signal. In the rotation angle detection sensors 38a and 38b, the state of the output signal becomes LOW level when the magnetic field on the S pole side acts, and the state of the output signal becomes HIGH level when the magnetic field on the N pole side acts. Therefore, when the rotation angle detection sensors 38a, 38b are positioned opposite to the magnets 42a, 42c,... With the outer peripheral side being the S pole side, the state of the detection signals output from the rotation detection sensors 38a, 38b is LOW level. When the position is opposite to the magnets 42b, with the N pole side as the outer peripheral side, the state of the detection signal output from the rotation angle detection sensors 38a, 38b is HIGH.
[0015]
The rotation angle detection sensors 38a and 38b are arranged at positions shifted by a central angle θ ° (θ = α ° / 2 in this embodiment) as well shown in FIG. Therefore, when the inner cylinder 30 (that is, the output shaft 8) rotates in the forward rotation direction, the state of the detection signal output from the rotation angle detection sensors 38a and 38b changes as shown in FIG.
For specific description, for example, it is assumed that the rotation angle detection sensors 38a, 38b and the magnets 42a, 42b, 42c are in the state shown in FIG. In the state shown in FIG. 3, the rotation angle detection sensor 38a is in a position facing the magnet 42b (the N pole is on the outer peripheral side), so that the detection signal is at a HIGH level. On the other hand, the detection signal of the rotation angle detection sensor 38b is at the LOW level due to the already passed magnet 42c (S pole is on the outer peripheral side). When the inner cylinder 30 is rotated by θ ° from this state, the magnet 42b (N pole is on the outer peripheral side) is positioned to face the rotation angle detection sensor 38b. For this reason, the detection signal output from the rotation angle detection sensor 38b is switched from the LOW level to the HIGH level. At this time, the state of the detection signal of the rotation angle detection sensor 38a remains at the HIGH level. Further, when the inner cylinder 30 is rotated and the inner cylinder 30 is rotated by α ° from the state of FIG. 3, the magnet 42a (S pole is on the outer peripheral side) is positioned to face the rotation angle detection sensor 38a. For this reason, the detection signal of the rotation angle detection sensor 38a is switched from HIGH level to LOW level. Similarly, when the inner cylinder 30 (output shaft 8) rotates by an angle θ ° after the detection signal state of the rotation angle detection sensor 38a is switched, the detection signal state of the rotation angle detection sensor 38b is switched. Become.
When the output shaft 8 rotates in the reverse direction, the detection signals of the rotation angle detection sensors 38a and 38b change as shown in FIG. 5 contrary to the above case. That is, when the output shaft 8 is further rotated by the angle θ ° after the detection signal state of the rotation angle detection sensor 38b is switched, the detection signal state of the rotation angle detection sensor 38a is switched.
[0016]
As apparent from the above description, the rotation angle detection sensors 38a and 38b switch the level of the detection signal every time the inner cylinder 30 (that is, the output shaft 8 of the oil unit 12) rotates α °. Therefore, the rotation angle detection sensors 38a and 38b output one pulse wave every time the output shaft 8 rotates 2 × α °, and the microcomputer 50 described later detects the rising edge and the falling edge of the pulse wave. Thus, a change in the rotation angle of the output shaft 8 is detected.
Here, as is apparent from FIGS. 4 and 5, an edge change occurs every time the output shaft 8 rotates by α ° / 2 in one of the detection signals of the rotation angle detection sensors 38a and 38b. Therefore, the minimum resolution of the change in the rotation angle of the output shaft 8 (forward rotation direction and reverse rotation direction) that can be detected by the rotation angle detection sensors 38a and 38b is α ° / 2.
[0017]
Further, the detection signals output from the two rotation angle detection sensors 38 a and 38 b are shifted in phase by α ° / 2, and the direction of the phase shift differs depending on the rotation direction of the output shaft 8. Therefore, the rotation direction of the output shaft 8 is detected by the phase shift of the detection signals output from the rotation angle detection sensors 38a and 38b. That is, the determination is made based on the input order of the detection signals (rising edge and falling edge) of the rotation angle detection sensor 38a and the detection signals (rising edge and falling edge) of the rotation angle detection sensor 38b.
A case where a detection signal as shown in FIG. 7 is measured will be specifically described as an example. In the example of FIG. 7, since the output shaft 8 is hammered, an edge change appears only in the detection signal output from the rotation angle detection sensor 38b between times t3 and t7.
First, the microcomputer 50 detects the rising edge of the detection signal of the rotation angle detection sensor 38a at time t1. At this time, the rotation direction is detected depending on which edge change of the rotation angle detection sensors 38a and 38b the edge change detected immediately before this edge change. Here, it is assumed that the edge change detected immediately before is the falling edge of the rotation angle detection sensor 38b. Therefore, it is determined that the main shaft 8 is rotating in the forward rotation direction, and the rotation angle of the main shaft 8 is increased by α ° / 2. Next, the rising edge of the detection signal of the rotation angle detection sensor 38b is detected at time t2. Therefore, it is determined that the output shaft 8 is rotating forward at time t2, and the rotation angle of the main shaft 8 is increased by α ° / 2. Similarly, at times t3 and t4, it is determined that the output shaft 8 is rotating forward, and the rotation angle of the main shaft 8 increases by α ° / 2.
On the other hand, at the time t5, the rising edge of the detection signal of the rotation angle detection sensor 38b is detected. Accordingly, an edge change is detected in the detection signal of the same rotation angle detection sensor 38b as at time t4, and it is determined that the rotation direction of the output shaft 8 has changed (that is, it is determined that the output shaft 8 has been reversed). For this reason, the rotation angle of the main shaft 8 decreases by α ° / 2. Similarly, at time t6, it is determined that the rotation direction of the output shaft 8 has changed and is rotating forward, and from time t7 to t9, it is determined that the output shaft 8 is rotating forward.
[0018]
The angle soft impact wrench 1 is provided with a trigger switch 22 for starting the motor M, and a battery for supplying power to the motor M, the microcomputer 50 described below, and the like at the lower end of the housing 3. The pack 24 is detachably attached.
[0019]
Next, the configuration of the control circuit of the angle soft impact wrench 1 will be described with reference to FIG. The control circuit of the angle soft impact wrench 1 according to the present embodiment is configured around a microcomputer 50 housed in the housing 3.
The microcomputer 50 is a microcomputer in which a CPU 52, a ROM 54, a RAM 56 and an I / O 58 are integrated into one chip, and are connected as shown in FIG. The ROM 54 of the microcomputer 50 stores a control program for automatically stopping the driving of the motor M, which will be described in detail later.
The rotation angle detection sensors (Hall ICs) 38a and 38b described above are connected to predetermined input ports of the I / O 58, and detection signals output from the rotation angle detection sensors 38a and 38b are input to the microcomputer 50. ing. Further, the battery pack 24 as a power source is connected to the microcomputer 50 via the power supply circuit 64 and is connected to the motor M via the drive circuit 62. Further, the motor M is controlled by the microcomputer 50 via the drive circuit 62 and the brake circuit 60.
When the motor M is driven, the output shaft 8 of the oil unit 12 rotates, and accordingly, a detection signal is input to the microcomputer 50 from the rotation angle detection sensors 38a and 38b. The microcomputer 50 performs the process described below based on the input detection signal, and stops the motor M by operating the brake circuit 60 at a predetermined timing.
[0020]
The RAM 56 of the microcomputer 50 is provided with storage registers R1 to R10 for storing edge changes of detection signals output from the rotation angle detection sensors 38a and 38b (see FIG. 8). The microcomputer 50 detects edge changes of the rotation angle detection sensors 38a and 38b at predetermined intervals, and stores the detected edge changes and their rotation directions in the storage registers R1 to R10. Specifically, “01” is stored when an edge change in the forward direction is detected, “FF” is stored when an edge change in the reverse direction is detected, and an edge change is detected. If not, “00” is stored. In the example shown in FIG. 8, while the edge change is stored in the storage registers R1 to R10, the main shaft 8 is rotated in the forward rotation direction by one edge change (that is, α ° / 2).
Note that the period in which the microcomputer 50 detects the edge change is sufficiently short (in this embodiment, 0.2 ms), so that no more than two edge changes occur during one period. The microcomputer 50 is programmed to store edge changes detected in order from the registers R1 to R10. When the edge changes are stored in all the storage registers R1 to R10, the information from the registers R2 to R10 is shifted to and stored in the registers R1 to R9, and the new edge change is stored in the register R10. It has been programmed. As a result, the edge change that occurred most recently is cleared in order.
[0021]
Next, the processing of the microcomputer 50 when tightening nuts using the angle soft impact wrench 1 configured as described above will be described with reference to the flowcharts shown in FIGS.
In order to tighten the nuts using the angle soft impact wrench 1, first, the operator engages the nuts with the socket attached to the tip of the spindle 2 and turns on the trigger switch 22. When the trigger switch 22 is turned on, the microcomputer 50 starts rotation of the motor M and performs the processing described below.
[0022]
When the trigger switch 22 is turned on, as shown in FIG. 9, the microcomputer 50 first resets the storage registers R1 to R10, the seating detection counter C, and the auto stop timer, and starts the motor M (step S10). The seating detection counter C is incremented by 1 when it is determined that the nuts are seated on the tightened member. The auto stop timer is a timer for determining whether or not to stop the motor M.
Once the initialization process is performed, the seating detection timer T is reset (step S12). The seating detection timer T is a timer that is required when performing seating detection processing (steps S14 to S34) described later.
[0023]
In step S14, the microcomputer 50 starts the first edge change detection process. The first edge change detection process will be described with reference to FIG.
As shown in FIG. 10, in the first edge change detection process, it is first determined whether or not an edge change has occurred in the detection signals from the rotation angle detection sensors 38a and 38b (S38). If no edge change has occurred (NO in step S38), "00" is stored in the storage register R (S40), the process returns to step S12 in FIG. 9, and the processes from step S12 are repeated.
On the other hand, if an edge change has occurred [YES in step S38], it is determined whether the edge change is in the forward direction or the reverse direction (S42). In the case of an edge change in the forward direction (YES in step S42), "01" is stored in the storage register (S44, S48), and in the case of an edge change in the reverse direction (NO in step S42), "FF" is stored in the storage register. Is stored (S46, S48). When the edge change is stored in step S48, the rotation angle change amount in the forward rotation direction (screw tightening direction) of the spindle 8 during T1ms (the first set time in the claims) before the edge change is generated. Is calculated (S50). Specifically, the calculation is performed by adding the edge changes stored in the storage registers R1 to R10. When step S50 ends, the process proceeds to step S16 in FIG.
[0024]
In step S16, the microcomputer 50 determines whether or not the rotation angle change amount calculated in step S50 of FIG. 10 is equal to or less than “set value 1”. In this embodiment, “set value 1” (first set value in the claims) is α °.
When the rotation angle change amount calculated in step S50 exceeds “set value 1” [NO in step S16], it is determined that the spindle 8 is not in a stopped state, and the process returns to step S12 to return from step S12. Repeat the process. On the other hand, if the rotation angle change amount calculated in step S50 is equal to or less than “set value 1” (YES in step S16), it is determined that the spindle 8 is in a stopped state, and the process proceeds to step S18. .
In step S18, the edge change detected in the first edge change detection process (specifically, steps S44 and S46 in FIG. 10) is stored in the variable r. The variable r is a variable for calculating the amount of change in the rotation angle of the spindle 8 during T2ms (second setting time in the claims) after the edge change occurs.
In step S20, as in step S18, the edge change detected in the first edge change detection process is stored in variable R. The variable R is a variable for calculating the amount of change in the rotation angle of the main shaft 8 in the forward rotation direction during T3ms (third set time in the claims) after the edge change occurs.
In step S24, it is determined whether the seating detection timer T has reached T2 ms. If the seating detection timer T has reached T2ms [YES in step S24], the process proceeds to step S28, and if the seating detection timer T has not reached T2ms [NO in step S24], the process proceeds to step S26 to change the second edge. Perform detection processing.
[0025]
The second edge change detection process in step S26 will be described with reference to FIG. As shown in FIG. 11, in the second edge change detection process, it is first determined whether or not an edge change has occurred in the detection signals from the rotation angle detection sensors 38a and 38b (S52). If no edge change has occurred [NO in step S52], "00" is stored in the registers R45 and r45, and the process proceeds to step S62.
On the other hand, if an edge change has occurred [YES in step S52], it is determined whether the edge change is in the forward direction or the reverse direction (S56). In the case of an edge change in the forward direction (YES in step S56), "01" is stored in the registers R45 and r45 (S58). In the case of an edge change in the reverse direction (NO in step S56), "FF" is stored in the register R45. , R45 is stored with “01” (S60).
In step S62, the value of the register R45 is added to the variable R, and the value of the register r45 is added to the variable r. As a result, the detected rotation angle change amount of the main shaft 8 is added to the variable R and the variable r. In step S62, the numerical value of the register R45 is further stored in the storage register. When step S62 ends, the process returns to step S24 in FIG. 9 and the processing from step S24 is repeated. Therefore, the processes in steps S24 and S26 are repeated until the seating detection timer T reaches T2 ms (that is, until the second edge change detection process is performed (T2 / 0.2 + 1) times).
[0026]
On the other hand, if YES in step S24 of FIG. 9 (when T2ms has elapsed from the edge change), it is determined whether or not the absolute value of the variable r is equal to or greater than “set value 2” (S28). That is, it is determined whether or not the spindle 8 has started rotating (forward rotation direction or reverse rotation direction) after the edge change detected in the first edge change detection process in step S14 has occurred. In this embodiment, “set value 2” (second set value in the claims) is the same value (α °) as “set value 1”.
If it is determined NO in step S28, it is determined that the edge change detected in the first edge change detection process is not at the oil pulse generation start time, and the process returns to step S12 and the processes from step S12 are repeated. If “YES” is determined in the step S28, it is determined that the edge change detected in the first edge change detecting process is the time when the oil pulse generation is started, and the process proceeds to the step S34.
In step S34, it is determined whether or not the seating detection timer T has reached T3ms. If the seating detection timer T has reached T3 ms [YES in step S34], the process proceeds to the motor stop process (S36) in step S36, and if the seating detection timer T has not reached T3ms [NO in step S34], step S32 is performed. The process proceeds to the third edge change detection process (S32).
[0027]
First, the third edge change detection process in step S32 will be described with reference to FIG.
As shown in FIG. 12, in the third edge change detection process, it is first determined whether or not an edge change has occurred in the detection signals from the rotation angle detection sensors 38a and 38b (S64). If no edge change has occurred [NO in step S64], "00" is stored in the register R45, and the process proceeds to step S74.
On the other hand, if an edge change has occurred [YES in step S64], it is determined whether the edge change is in the forward direction or the reverse direction (S68). In the case of an edge change in the forward direction (YES in step S68), “01” is stored in the register R45 (S70), and in the case of an edge change in the reverse direction (NO in step S68), “FF” is stored in the register R45. (S72).
In step S74, the value in the register R45 is added to the variable R. As a result, the rotation angle change of the main shaft 8 detected every 0.2 ms is added to the variable R. In step S74, the numerical value of the register R45 is further stored in the storage register. When step S74 ends, the process returns to step S30 in FIG. 9 and the processing from step S30 is repeated. Therefore, the processes from steps S28 to S34 are repeated until the seating detection timer T reaches T3ms (that is, until the third edge detection process is performed ((T3-T2) /0.2) times).
[0028]
Next, the motor stop process in step S36 will be described with reference to FIG.
As shown in FIG. 13, in the motor stop process, first, the value of the variable R (that is, the rotation of the spindle 8 in the forward rotation direction until T3 ms elapses from the edge change detected in the first edge change detection process). It is determined whether or not the (angle change amount) is equal to or less than “set value 3” (S76). The “set value 3” is preferably set to an appropriate value according to the type of screws (for example, mechanical screws such as wood screws, bolts and nuts) and the type of tightening work.
If the variable R exceeds the “set value 3” (NO in step S76), it is determined that the screws are not seated, and the process proceeds to step S84. If the variable R is within the “set value 3” (YES in step S76), Proceeding to step S78 assuming that the screws are seated. That is, in this embodiment, the amount of change in the rotation angle at which the main shaft 8 rotates in the forward rotation direction is reduced by one oil pulse (impact force) after the screws are seated, compared to before the screws are seated. To determine the seating of the screws.
If YES in step S76, 1 is added to the seating detection counter C (S78), and it is determined whether or not the seating detection counter C is 2 (S80). If the seating detection counter C is not 2 [NO in step S80], the process proceeds to step S84 to perform the second seating detection. On the other hand, if the seating detection counter C is 2 [YES in step S80], the auto-stop timer is started (S86), and it is determined whether or not the auto-stop timer has reached the set time T4 (fourth set time in the claims). (S88). If the auto stop timer has not reached the set time T4 [NO in step S88], the process waits until the auto stop timer reaches the set time T4. On the other hand, when the auto stop timer has reached the set time T4 [YES in step S88], the motor M is stopped (S90).
On the other hand, if it progresses to step S84, it will be determined whether the seating detection timer T corresponded to T5ms (S84). If the seating detection timer T does not coincide with T5ms [NO in step S84], the process waits until the seating detection timer T reaches T5ms. If the seating detection timer T coincides with T5 ms [YES in step S84], the process returns to step S12 in FIG. 9 and the processing from step S12 is repeated. Therefore, when the seating determination is performed, the next seating determination is not performed until T5 ms (the fifth set time in the claims) elapses. Therefore, camera shake or the like due to the seating of the screws does not affect the next seating determination, so that the seating of the screws can be detected with high accuracy.
[0029]
As apparent from the above description, in this embodiment, the edge change and the rotation direction of the rotation angle detection sensors 38a and 38b are stored in the storage registers R1 to R10 at predetermined intervals, whereby the edge change is detected. The motion state (stop or rotation) of the front spindle 8 is determined. If it is determined that the main shaft 8 is stopped, the movement state (stop or rotation) of the main shaft 8 after the edge change is detected is further measured, and the time when the edge change occurs is determined as oil. It is determined whether or not it is a pulse generation start time. Therefore, since the oil pulse generation start time is specified by the rotation angle detection sensors 38a and 38b that detect the change in the rotation angle of the main shaft 8, the conventionally required impact sensor can be dispensed with.
[0030]
(Example 2) Next, a tightening tool (angle soft impact wrench) according to a second example embodying the present invention will be described with reference to the drawings.
The tightening tool according to the second embodiment also has the same mechanical configuration as the tightening tool according to the first embodiment. However, the tightening tool of the second embodiment is used for tightening two types of members to be tightened (hard joint material (specifically, iron plate) and soft joint material (specifically, wood plate)). It is done. For this reason, the ROM 54 of the microcomputer 50 stores the motor stop condition for the hard joint material (motor drive time T1 after seating) and the motor stop condition for the soft joint material (motor drive time T2 after seating (where T2> T1)) is stored. Further, the ROM 54 of the microcomputer 50 determines whether the tightened member to be tightened is a hard joint material or a soft joint material. In the case of a hard joint material, the motor M is driven for a motor driving time T1 after sitting, In the case of a soft joint material, a program for driving the motor M for the motor driving time T2 after sitting is assembled. Therefore, the difference between the first embodiment and the second embodiment is that the hardware configuration is the same except that the program of the microcomputer 50 is different. For this reason, about the mechanical structure of the fastening tool which concerns on 2nd Example, while the code | symbol of 1st Example is used, the description is abbreviate | omitted. Only the differences from the first embodiment will be described below.
[0031]
Also in the tightening tool of the second embodiment, the microcomputer 50 performs processing according to the flowchart shown in FIG. Further, the first edge change detection process (FIG. 10), the second edge change detection process (FIG. 11), and the third edge change detection process (FIG. 12) in the flowchart shown in FIG. 9 are the same as in the first embodiment. Done. However, in the second embodiment, the motor stop process in step S36 shown in FIG. 9 is different from the motor stop process in the first embodiment. Hereinafter, the motor stop process according to the second embodiment will be described with reference to the flowchart shown in FIG.
[0032]
As shown in FIG. 14, in the motor stop process of the second embodiment, first, it is determined whether or not the seating detection flag F is “1” (S92). The seating detection flag F is a flag indicating whether or not the screws are seated, and becomes “1” when seated, and becomes “0” when not seated. The seating detection flag F is cleared in the initialization process in step S10 of FIG. 9, and the determination in step S92 is always NO in the motor stop process performed first after the motor M is started.
If the seating detection flag F is not “1” (NO in step S92), the process proceeds to step S94, and the value of the variable R (that is, until 5.0 ms elapses from the edge change detected in the first edge change detection process). It is determined whether or not the amount of change in the rotation angle of the main shaft 8 in the forward rotation direction during the period is equal to or less than “set value 3”. If the variable R exceeds the “set value 3” (NO in step S94), it is determined that the screws are not seated, and the process proceeds to step S104. If the variable R is within the “set value 3” (YES in step S94), Proceeding to step S96 assuming that the screws are seated.
In step S96, 1 is added to the seating detection counter C, and then it is determined whether or not the seating detection counter C is 2 (S98). If the seating detection counter C is not 2 [NO in step S98], the process proceeds to step S104 to perform the second seating detection. On the other hand, if the seating detection counter C is 2 (YES in step S98), the seating detection flag F is set to “1”, the auto-stop timer is started (S100), and the process proceeds to step S104.
In step S104, it is determined whether or not the seating detection timer T matches 15 ms (S104). If the seating detection timer T does not match 15 ms [NO in step S104], the process waits until the seating detection timer T reaches 15 ms. If the seating detection timer T coincides with 15 ms [YES in step S104], the process returns to step S12 in FIG. 9 and the processing from step S12 is repeated. Therefore, in the second embodiment, even after the auto stop timer is started, the process returns to step S12 in FIG. 9 and the processing from step S12 is performed.
[0033]
On the other hand, if YES in step S92 (that is, if the seating detection flag F is “1” and the auto stop timer is started), the value of variable R (ie, first edge change detection processing (S14)) is set to variable RR. The amount of change in the rotation angle of the main shaft 8 in the forward rotation direction from the edge change detected in step 1 to the present time) is added (S106), and it is determined whether or not the auto stop timer has reached the “set time” (S108). The “set time” in step S108 is the motor driving time T1 for the hard joint material.
If the auto-stop timer is not “set time” [NO in step S108], the process proceeds to step S104. Accordingly, the processing from step S12 in FIG. 9 is repeated again, and the variable RR stores the amount of change in the rotation angle of the main shaft 8 in the forward rotation direction after the screws are seated.
On the other hand, when the auto stop timer reaches the “set time” [YES in step S108], the process proceeds to step S110. In step S110, the variable RR (that is, the amount of change in the rotation angle of the main shaft 8 in the forward rotation direction until the “set time” elapses after seating detection (corresponding to the cumulative rotation angle amount in the claims)) is “ It is determined whether or not the angle is equal to or greater than the “set angle” (S110).
If the variable RR is less than the “set angle” [NO in step S110], it is determined that the member to be tightened is a hard joint material, and the motor M is stopped as it is (S116). On the other hand, if the variable RR is greater than or equal to the “set angle” (YES in step S110), it is determined that the tightened member to be tightened is a soft joint material, and the “set time” is multiplied by k (k> 1). (S112). That is, the motor driving time T2 that is the “set time” for the soft joint material is changed. Then, it waits until the auto stop timer reaches the “set time” (S114), and when the auto stop timer reaches the “set time”, the motor is stopped and the process is terminated (S116).
[0034]
As is apparent from the above description, in the second embodiment, a rotation angle change amount (cumulative rotation angle amount) in the forward rotation direction of the main shaft 8 after seating detection is calculated, and the calculated rotation angle change amount is used as a threshold value. Compare with Then, it is determined that the tightened member to be tightened is a soft joint material when the calculated rotation angle change amount is equal to or greater than the threshold value, and the tightened member is tightened when the calculated rotation angle change amount is less than the threshold value. Is determined to be a hard joint material. If it is determined that it is a hard joint material, the motor is driven for a driving time T1 after sitting, and if it is determined that it is a soft joint material, the motor is driven for a driving time T2 after sitting. Therefore, since the motor driving time after the seating is automatically changed according to the type of the tightening member, the screws can be tightened with an appropriate tightening torque even if the type of the tightening member is different.
[0035]
The preferred embodiments of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.
For example, in each of the above-described embodiments, the rotation of the motor M is stopped after a predetermined time after the screws are seated. However, the present invention is not limited to such an example, and the impact force (striking) applied to the main shaft. The driving of the motor M may be stopped when the number of hits reaches a predetermined number.
In the above-described embodiment, the oil unit is used as the impact force generation mechanism. However, as a mechanism for generating the impact force, various other mechanisms such as a mechanical impact force generation mechanism for hitting the anvil with a hammer are used. The present invention can also be applied to a fastening tool having the same.
Furthermore, in the second embodiment described above, the hard joint material or the soft joint material is determined based on the amount of change in the rotation angle of the main shaft in the normal rotation direction. The amount of change in the rotation angle in the direction (or the amount of change in the average rotation angle of one oil pulse) may be calculated, and the type of screw may be determined based on this value.
In the second embodiment described above, there are two types of tightening members for tightening screws, hard joint material and soft joint material, but there are two types of tightening members for tightening screws. Not limited. For example, as shown in FIG. 18, a plurality of threshold values for comparison with the cumulative rotation angle amount of the main shaft are provided, and the screws for three or more types of tightening members are compared by comparing the plurality of threshold values with the cumulative rotation angle amount of the main shaft. Can be tightened. In the case of the example shown in FIG. 18, the clamped member 1 is determined that the cumulative rotation angle amount of the main shaft is less than the threshold value 4, and the clamped member 2 is determined that the cumulative rotation angle amount of the main shaft is the threshold value 4 to the threshold value 3. When the cumulative rotation angle amount of the main shaft is between the threshold value 3 and the threshold value 2, it is determined as the tightened member 3, and when the cumulative rotation angle amount of the main shaft is between the threshold value 2 and the threshold value 1, it is determined as the tightened member 4. Then, when the cumulative rotation angle amount of the spindle is equal to or greater than the threshold value 1, it is determined that the member 5 is to be fastened. If the type of the member to be tightened can be determined, the motor may be stopped under the motor stop condition corresponding to the type.
[0036]
In addition, the technical elements described in the present specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.
[Brief description of the drawings]
FIG. 1 is a partial cross-sectional side view of an angle soft impact wrench according to an embodiment.
FIG. 2 is a cross-sectional view showing the structure of a bearing device.
FIG. 3 is a diagram schematically showing a positional relationship between a magnet incorporated in a bearing device and a rotation angle detection sensor.
FIG. 4 is a diagram illustrating a state of detection signals output from two rotation angle detection sensors when an output shaft rotates forward.
FIG. 5 is a diagram illustrating a state of detection signals output from two rotation angle detection sensors when the output shaft rotates in reverse.
FIG. 6 is a block diagram showing a configuration of a control circuit of an angle soft impact wrench.
7 is a diagram schematically showing a relationship between detection signals of rotation angle detection sensors 38a and 38b and a rotation angle change of a main shaft 8. FIG.
FIG. 8 is a diagram showing a configuration of a storage register provided in the RAM of the microcomputer.
FIG. 9 is a flowchart of auto-stop processing performed by a microcomputer.
FIG. 10 is a flowchart of first edge change detection processing;
FIG. 11 is a flowchart of second edge change detection processing;
FIG. 12 is a flowchart of third edge change detection processing;
FIG. 13 is a flowchart of motor stop processing.
FIG. 14 is a flowchart of motor stop processing according to the second embodiment.
FIG. 15 is a diagram illustrating an example of a transition of a cumulative rotation angle of a main shaft when a mechanical screw made of a hard material is tightened and a transition of a rotation angle of the main shaft per impact (one impact force) after sitting.
FIG. 16 shows changes in the cumulative rotation angle of the main spindle when a soft mechanical screw (hereinafter referred to as soft joint material) is tightened, and changes in the rotation angle of the spindle per impact (one impact force) after seating. FIG.
FIG. 17 is a diagram showing an example of transition of the cumulative rotation angle of the main shaft after sitting on each of the hard joint material and the soft joint material.
FIG. 18 is a diagram for explaining a modification of the second embodiment;
[Explanation of symbols]
１ ・ Angle soft impact wrench
8 ..Output shaft
10. Bearing device
12. Oil unit
22. Trigger switch
30 .. Inner cylinder
34. ・ Outer cylinder
36 .. Sensor mounting member
38a, 38b ... rotation angle detection sensor
40 ・ ・ Magnet mounting member
42 .. Magnet

Claims (4)

A tightening tool for tightening screws to have a tightening torque set for a plurality of types of members to be tightened,
A motor,
A main shaft engageable with screws,
When the load acting on the main shaft is interposed between the motor and the main shaft and the load acting on the main shaft is less than the predetermined value, the rotational torque from the motor is directly transmitted to the main shaft to rotate the main shaft, and the load acting on the main shaft exceeds the predetermined value Is an impact force generating means for generating an impact force to rotate the spindle,
Rotation angle detection means for detecting the rotation angle change of the main shaft and its rotation direction;
Means for storing a plurality of automatic stop conditions for automatically stopping the motor;
“Cumulative rotation angle amount in the screw tightening direction of the main shaft” and “rotation angle amount per impact force of the main shaft” obtained from the rotation angle change of the main shaft detected by the rotation angle detecting means after the screws are seated. A motor that selects one automatic stop condition from among a plurality of automatic stop conditions stored in the automatic stop condition storage means and stops the motor when the selected automatic stop condition is satisfied. Control means;
Tightening tool with   The motor control means (1) is based on a change in rotation angle of the main shaft detected by the rotation angle detection device and its rotation direction, and the accumulated rotation angle amount in the screw tightening direction of the main shaft within a predetermined time set after the screws are seated. (2) The type of the tightening member is determined from the calculated cumulative rotation angle amount, and (3) When the automatic stop condition corresponding to the determined type of the tightening member is satisfied The tightening tool according to claim 1, wherein the motor is stopped.   The tightening tool according to claim 1 or 2, wherein the automatic stop condition is a motor driving time after the screws are seated.   The tightening tool according to claim 1 or 2, wherein the automatic stop condition is the number of times an impact force is generated from the impact force generation means after the screws are seated.

Images