JPH11268011A - Veneer lathe and log cutting method using same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To carry out the good cutting for forming a veneer to be thus formed to conform to a preset thickness even when recesses are formed on the periphery of a log. SOLUTION: A log 1 is supported by a spindle S, and cutting is carried out by moving a plane stock 4 and rolls 28 and 34 are brought into contact with the peripheral face of the log 1 at the latest when the plane stock 4 reaches the first position, and then the rolls are moved following the peripheral face. When the plane stock 4 reaches the first position, cutting is continued in the same state that a recessed section 1a larger than the given size on the peripheral face of the log 1, and when the plane stock 4 reaches the second position, the movement of the plane stock 4 and the rolls 28 and 34 is discontinued, and then the spindle S is moved back to the position whereon the plane stock 4 is not disturbed by the spindle, and then the plane stock 4 and the rolls 28 and 34 are moved again to carry out the cutting, and when the plane stock reaches the third position, the cutting is completed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for cutting a veneer veneer (hereinafter referred to as veneer) by cutting a rotating log with a blade.

[0002]

2. Description of the Related Art Conventionally, in order to increase the rate of obtaining a veneer from a log, a plane table with a cutting tool is moved toward the log while supporting a rotating log with spindles abutting on both ends. The raw wood is cut and, at the latest, until the radius of the raw wood reaches a predetermined value, a roll is brought into contact with the peripheral surface of the raw wood, and thereafter, the roll is moved following the peripheral surface of the raw wood whose radius becomes smaller, and the predetermined radius and It is described in Japanese Patent Application Laid-Open No. 4-65201, for example, that the spindle is separated from the tip and the cutting is further continued until the radius of the log becomes smaller than the spindle. In this apparatus, FIG. 1 is a side view, which is a partial cross-sectional view, FIG. 2 is a partial plan view, as viewed from the dashed line AA of FIG. 1 in the direction of the arrow, and dashed line B of FIG.
It is configured as shown in FIG. That is, for example, a piercing roll 3 having a large number of piercing bodies 3a is fixed at a predetermined interval to a rotating shaft 5 arranged on the plane table 4 in a direction perpendicular to the direction in which the plane table 4 travels, facing the cutting tool 2. The nose bar 10 is provided between the adjacent piercing rolls 3. FIG.
Although not shown in FIG. 2, as shown in FIG. 2, at both ends 5 a of the rotating shaft 5, a bearing 6 fixed to the plane table 4 and rotatably supporting the both ends 5 a is provided outside the bearing 6 in the orthogonal direction. A chain 8 is placed around a sprocket (not shown) fixed to both ends. The chain 8 is driven and driven by a motor 7 fixed on a nose bar base 9.

[0003] Cutting is performed by such an apparatus as follows.
As long as there is a recess on the peripheral surface of the log 1, the spindle S
, And the plane table 4 is moved toward the log 1 to perform cutting with the blade 2. When the cutting progresses and the log 1 becomes substantially circular, the rolls 28 and 34 are controlled by the controller.
Is controlled to move the roll 28 in the horizontal direction and the roll 34 vertically upward at the same speed as the moving speed of the plane table 4 thereafter. Next, when the radius of the log 1 becomes a preset value, the spindle S is separated from the log 1 and is cut by the cutting tool 2 while supporting the log 1 by the rolls 28 and 34 and the plane table 4, so that the spindle S is obstructed. Therefore, the log 1 can be cut to a smaller radius. In this apparatus, in order to increase the productivity, in order to separate the spindle S from the log 1 without interrupting the cutting of the log 1, when the cutting progresses and the plane table 4 reaches a position at a predetermined distance from the rotation center of the spindle S, the spindle S Is retreated as follows. That is, before the plane table 4 reaches the position of the spindle S indicated by the solid line in FIG. 2, the spindle S must be retracted to the position S1 indicated by the two-dot chain line. Therefore, the time required for the spindle S to start retreating and reach the position S1 is T1, and at the position of the plane table 4 when the spindle S starts retreating, the bearing 6 or the chain 8 provided on the plane table 4 is bridged. The distance between the tip of the sprocket 9 in the traveling direction (hereinafter referred to as the tip of the plane table 4) and the rotation center of the spindle S is x
Then, the distance x needs to be a distance such that the tip of the plane table 4 that has advanced from the position does not reach the position of the spindle S shown by the solid line in FIG. 2 after the elapse of the time T1. Therefore, in the above apparatus, when the distance between the tip of the plane table 4 and the rotation center of the spindle S becomes x, the spindle S is started to retreat according to a control signal from the control device, and FIG.
Further, as shown in FIG. 5 which is a partial side view showing the direction of the arrow from the alternate long and short dash line CC in FIG. 4, cutting is performed until the log 1 becomes smaller.

[0004]

However, in the veneer race controlled as described above, when the tip of the plane table 4 reaches the position of the distance x, the log 1 is still formed with a concave portion 1a around its periphery as shown in FIG. In some cases, if the spindle S is separated from the log 1 in this state, the following problem occurs. That is, the rotating log 1 is supported by the rolls 28 and 34 and the plane table 4. For example, when the concave portion 1a of the rotating log passes through the roll 28, the roll 28 and the log 1 The center of rotation of the log 1 moves in the horizontal direction without being fixed at one point, and the thickness of the veneer obtained by cutting the log 1 becomes smaller than the set value, making it unusable. It was impossible to cut the log 1 and the yield was greatly reduced.

[0005]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides a veneer lace in which a planing table provided with a cutting tool is supported on a log while supporting a log that is rotated by spindles abutting on both ends. Continue to cut the log by moving it toward the first position at the latest until the plane table reaches the first position. Following the movement, when the plane table reached the first position, it was determined whether or not the peripheral surface of the raw wood had a concave portion that was greater than a predetermined value. Continue cutting in the state, when the plane table reaches the second position, stop the movement of the plane table and the roll, then move the spindle away from both lips and retreat to a position that will not hinder the progress of the plane table, then again the plane table and the roll Start moving wood When cutting is performed, when the plane table reaches the third position, the movement of the plane table and the roll is stopped to end the cutting, and if there is no concave portion larger than a predetermined value, the spindle is separated from the tip and orthogonal to the moving direction of the plane table. When the plane table reaches the third position, the movement of the plane table and the rolls is stopped to end the cutting. Also, as a device, having a working member, a spindle provided with advance and retreat freely, a plane table with a blade, which is reciprocally movable by the operating member with respect to these spindles, and a plane table position detecting device for detecting a position of the plane table with respect to the spindle. , An appropriate number of rolls, which can contact and separate the peripheral surface of the raw wood by the operating member and move following the peripheral surface of the raw wood, the radius of which decreases with the cutting after the contact, and A judgment device for judging the presence or absence of a concave portion, and a suitable number of rolls are brought into contact with the peripheral surface of the raw wood before the plane table moving toward the raw wood supported by the spindle reaches the first position at the latest, and After that, it moves following the peripheral surface of the log, and when it is detected from the detection device that the plane table has reached the first position, when a signal having the concave portion is output from the determination device,
If the detecting device detects that the plane table has reached the second position without issuing a new operation signal, the movement of the plane table and the roll is stopped, and then the spindle is separated from the both ends to hinder the progress of the plane table. After moving the plane table and the roll back, the movement of the plane table and the roll is started again to cut the raw wood, and when the detection device detects that the plane table has reached the third position, the movement of the plane table and the roll is stopped. Stopping, on the other hand, when it is detected from the detection device that the plane table has reached the first position, when a signal without the concave portion is issued from the determination device, the spindle is moved away from the tip and the direction of movement of the plane table. A control mechanism for controlling each operating member so as to start retreating in a direction perpendicular to the plane and then stop the movement of the plane table and the roll when the plane table reaches the third position. In the above, `` applying an appropriate number of rolls to the peripheral surface of the log and moving the rolls to follow the peripheral surface of the log having a smaller radius thereafter '' means that the roll is appropriately adjusted with the cutting edge of the blade provided on the plane table. The peripheral surface of each of the several rolls is positioned approximately equidistant from the center of the spindle, strictly through the cutting edge of the blade, and on an Archimedes spiral curve in consideration of the thickness of the veneer. This means that each roll is moved so that there is a surface, and thereafter each roll is moved so that each peripheral surface of the roll is also on the spiral curve that changes as the plane table moves. Note that the first position, the second position, and the third position refer to the positions defined below. A first position: when the moving plane table reaches the first position, the spindle starts retreating in a direction perpendicular to the direction of movement of the plane table, away from the tip, and then the plane table moves to the position of the spindle; A position where the spindle retracts to a position where it does not hinder the movement of the plane table. 2nd position: A position on the log side from the first position, where the end of the plane table on the log side does not come into contact with the spindle in contact with the wood opening. Third position: a position where cutting of the raw wood ends. Moreover, you may comprise as follows. That is, a center spindle which has an operating member and is provided with a movable back and forth, a spindle which is provided at least one layer outside the center spindle, and a blade which can reciprocate with respect to these spindles by the operating member. Plane table, plane table position detection device that detects the position of the plane table with respect to the spindle, and moves along the peripheral surface of the raw wood, which can be abutted and separated by the operating member and can be freely separated from the circumference of the raw wood, and the radius decreases as the blade is cut after the abutment An appropriate number of rolls, a judging device for judging the presence or absence of a concave portion having a predetermined size or more on the peripheral surface of the log, and a plane table moving toward the log supported by the spindle group reaches the first position at the latest. A suitable number of rolls are brought into contact with the peripheral surface of the log, and thereafter are moved to follow the peripheral surface of the log, and the log is moved only by the central spindle and the single spindle. In a more supported state, and when it is detected from the detection device that the plane table has reached the first position, when a signal having the concave portion is issued from the determination device, each member is similarly moved, and the plane table is moved. When the detection device detects that the plane table has reached the second position, the movement of the plane table and the rolls is stopped, and then only the single spindle is moved away from both the open ends and retracted to a position that does not hinder the advance of the plane table. After that, the movement of the plane table and rolls is started again, and the log is cut, and the plane table is
When the detection device detects that the plane has reached the position, the movement of the plane table and the roll is stopped. On the other hand, when it is detected from the detection device that the plane table has reached the first position, the determination device When a signal without the concave portion is issued from
Separate only the heavy spindle from the tip and start retreating in the direction orthogonal to the direction of movement of the plane table.
Is provided with a control mechanism for controlling each of the operating members so as to stop the movement of the plane table and the roll when reaching the position. In the above description, the first position, the second position, and the third position refer to the positions defined below. First position: When the moving plane table reaches the first position, the single spindle starts retreating in a direction perpendicular to the direction of movement of the plane table, separating from the tip, and then the single plane spindle moves to the first position. A position where the single spindle retracts to a position where it does not hinder the movement of the plane table when it reaches a certain position. Second position: a position on the log side from the first position, where the tip of the plane table on the log side does not come into contact with the single spindle in contact with the tip. Third position: a position closer to the log than the second position, and a position where the log-side end of the plane table does not contact the center spindle in a state where it is in contact with the tip. In the above description, "applying an appropriate number of rolls to the peripheral surface of the log and moving the rolls following the peripheral surface of the log having a smaller radius thereafter" means the same as above.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The following embodiments of the present invention will be described. In the present embodiment, FIG.
This will be described using the device shown in FIG. That is, as shown in FIG. 1 which is a cross-sectional side view explanatory diagram, a pair of spindles S provided so as to be able to advance and retreat in the axial direction of the log 1 and the log 1 rotatably supported by the spindle S. The piercing roll 3 and its related members are configured as follows in a veneer race composed of a cutting tool 2 for cutting piercing and a plane table 4 provided with a piercing roll 3. That is, as shown in FIGS. 1, 2 and 3, the piercing roll 3 has a disk shape having a piercing body 3a around the piercing roll 3 and is spaced apart from the rotating shaft 5 by a predetermined distance in the axial centerline direction of the rotating shaft 5. Many are fixed in. A nose bar 10 as a pressure bar is provided between the adjacent piercing rolls 3 with an upper end fixed to a nose bar base 9 integrated with the plane base 4. As shown in FIG. 2, the rotating shaft 5 is rotatably supported at both ends 5a thereof by bearings 6 fixed to a nose bar base 9, and further has sprockets (not shown) fixed outside the both ends 5a. The chain 8 for transmitting the power of the motor 7 provided on the nose bar base 9 via a one-way clutch (not shown) is stretched, so that the piercing roll 3 constantly rotates in the direction shown by the arrow in FIG. Have been allowed.

As shown in FIG. 1, two female screws (not shown) are formed on the plane table 4 as a first moving mechanism at intervals in a direction orthogonal to the movement direction of the plane table 4 described later. Although not shown, the base 11 which is a part of the veneer lace and is not rotatably held and is rotatably held therein is inserted into each female screw. As a log diameter detecting mechanism for detecting the radius of the log, a rotary encoder for detecting the distance between the rotation center of the log 1 and the position of the plane table 4 by measuring the number of rotations of the screw 14 is provided on the screw 14. And a variable-speed drive source 16 such as a servomotor for rotating the screw 14. In these configurations, the two screws 14 are integrally rotated by the variable speed drive source 16 under the control of the control mechanism 20 described later, so that the plane table 4 can be moved at any speed or at a predetermined speed. Is moved in the horizontal direction indicated by the arrow in FIG.

A pair of spindles S are provided on a base 11 and are reciprocally movable with respect to the log 1 by a hydraulic cylinder (not shown) as a spindle operating mechanism. As shown in FIG. The rotation speed measuring device 17 includes a rotary encoder or the like as a rotation speed measurement mechanism for measuring the rotation speed of the spindle S per unit time, and the variable speed drive source 18 includes a DC motor or the like that drives the spindle S to rotate. A center drive is provided.
In these configurations, even if the diameter of the log 1 is reduced by the cutting blade 2 as the plane table 4 moves toward the log and the diameter of the raw wood 1 decreases, the spindle S always rotates at the same peripheral speed and is cut by the cutting blade 2 to produce a single plate. In order to obtain T, a control mechanism 20, which will be described later, which has received a signal from the detector 15, controls the rotation speed to increase in relation to the distance between the rotation center of the log 1 and the plane table 4, and the axis of the log is A part of power required for cutting the log 1 is supplied to the core.

At a position opposite to the stepping screw 14 on the opposite side of the plane table 4 about the spindle S, as shown in FIG. 1, a second moving mechanism is similarly spaced in a direction orthogonal to the moving direction of the plane table 4. Then, the two screws 21 are arranged so as to be rotatably held on a base 23 which is a part of a veneer lace (not shown). The two screws 21
2, two female screws (not shown) formed to engage with the screws 21 respectively. Each of the screws 21 includes a rotary encoder or the like, and a detector 2 for detecting a distance between a rotation center of the log 1 and a peripheral surface of a roll 28 described later.
5. A variable speed drive source 26 comprising a servomotor or the like is provided, and a screw 21 rotated by the variable speed drive source 26 is provided.
The support 22 is guided so as to linearly and horizontally move on a base 23 arranged horizontally as indicated by an arrow.

On the other hand, on the spindle S side of the support table 22,
A roll 28 is rotatably provided via a bearing 30 (see FIG. 2), and a shaft is rotated on a top surface of the support base 22 as a rotation speed measuring mechanism to measure a peripheral speed of the roll 28. Is fixed, and a timing belt (not shown) is wound around the roll 28 and the pulse counter 29. The rotation signal of the roll 28 transmitted to the pulse counter 29 is transmitted to the control mechanism 20.
The number of rotations of the log 1 per unit time is measured by using the signal from the detector 15 as described later.
In these configurations, the screw 21 is integrally rotated by the variable-speed drive source 26 based on the control of the control mechanism 20 described later, so that the roll 28 together with the support table 22 has an arbitrary speed or a predetermined speed. 1 in the direction indicated by the arrow in FIG. Below the spindle S, a support table 3 is provided.
1 is provided so as to be vertically movable along a base 32 which is a part of the veneer race, and a roll 34 is provided on the support base 31 via a bearing 33 (see FIG. 4) so as to be able to rotate freely. This support 31
Similarly to the support table 22, a screw 35 rotatably provided on the base table 32 is provided, and a rotary encoder or the like is provided to detect a distance between a rotation center of the log 1 and a peripheral surface of a roll 34 described later. A variable speed drive source 37 including a detector 36 and a servomotor for rotating the screw 35 is provided.

In these configurations, a control mechanism 2 to be described later
By controlling the screw 35 integrally with the variable speed drive source 37 based on the control of 0, the roll 34 together with the support base 31 can be moved at an arbitrary speed or a predetermined speed in the direction indicated by the arrow in FIG. It is moved to. On the other hand, the determination switch 41, which is normally OFF and sends an ON signal while being manually pressed by the driver, is connected to the control mechanism. In addition to the judgment switch 41, the driver manually turns ON and OFF.
By doing so, the hydraulic cylinder for moving the spindle S back and forth, the motor 7, the variable speed drive sources 16, 18, 26 and 37
A switch (not shown) for outputting a signal to activate or deactivate at the same time or independently is provided.

With the above configuration, the control mechanism 20 is configured to control each member as follows. That is, in response to a switch operation (hereinafter, referred to as a switch operation) by the driver, the cutting edge of the blade 2 provided on the plane table 4 and the peripheral surfaces of the rolls 28 and 34 provided on the support base 22 are substantially equal to each other with the spindle S as a center. As in the position of the distance, strictly speaking, the position on the Archimedean spiral curve considering the thickness of the veneer,
The plane table 4, the support table 22, and the support table 31 are put on standby. In this state, similarly, the motor 7 is operated by the switch operation to rotate the piercing roll 3 and the variable speed drive source 18 is operated to rotate the spindle S supporting both ends of the log 1 to rotate the log 1. Upon receiving the signal of the number of rotations per unit time of the spindle S, ie, the log 1, calculated by the rotation measuring device 17, the control mechanism 20 determines the thickness of the veneer to be cut to a desired constant value based on this signal. Log 1 to do
An operation signal (hereinafter, referred to as a first operation signal) to the variable-speed drive sources 16, 26, and 37 so that the amount by which the plane table 4, the support table 22, and the support table 31 move toward the log 1 per one rotation is constant. ). The plane table 4 and the support table 22
During the movement of the support 31, the roll 28 is driven to rotate by the rotation of the log 1, so that the peripheral speed of the log 1 is obtained by the pulse counter 29. The control unit 20 calculates the number of rotations per unit time of the log 1 per minute time set in advance by the control mechanism 20 based on the signal of the distance between the rotation center of the plane and the position of the plane table 4. (Hereinafter, referred to as a second operation signal) such that the amount of movement of the plane table 4, the support table 22, and the support table 31 toward the log 1 per rotation of the log 1 is constant so that the thickness of the veneer is constant. At this point, the first operation signal is still transmitted to the variable speed driving sources 16, 26 and 37, and the second operation signal is not transmitted.

Cutting proceeds from the above state, and the signal from the detector 15 causes the distance between the center of rotation of the log 1 and the tip of the plane table 4 to reach the set x as shown in FIG. When the control mechanism 20 detects that the vehicle has reached the first position (hereinafter, referred to as a first position), the control mechanism 20 emits a buzzer sound. Control mechanism 2
If the determination switch 41 is kept OFF within a set time of several seconds after the buzzer sound is output, the first operation signal transmitted to the variable speed drive sources 16, 26 and 37 first. Is switched to the second operation signal, and the movement of the plane table 4, the support table 22, and the support table 31 is similarly continued by the second operation signal. Next, after the movement of the plane table 4, the support table 22 and the support table 31 by the second operation signal is continued, a signal for retreating the spindle S and separating from the log 1 is output to the hydraulic cylinder. Further, when the plane table 4, the support table 22, and the support table 31 move and the plane table 4 reaches the preset third position, the control mechanism 20 stops the variable-speed drive sources 16, 26, and 37, and is slightly delayed. A signal for stopping the rotation of the motor 7 is issued.

On the other hand, when the determination switch 41 is turned on within a set time of several seconds after the buzzer sound is output, the control mechanism 20 does not output a new operation signal at this time.
Next, the detector 15 indicates that the interval between the center of rotation of the log 1 and the tip of the plane table 4 has reached a preset position (hereinafter referred to as a second position) at which the distance becomes slightly larger than the radius of the spindle S. , A signal for stopping the operation of the variable speed drive sources 16, 26 and 37 is issued. A few seconds after the signals for stopping the variable speed drive sources 16, 26 and 37 are issued, a signal for stopping the operation of the variable speed drive source 18 and a signal for stopping the rotation of the motor 7, and then a signal for retracting the spindle S are issued. To the hydraulic cylinder.
Further, after a lapse of time necessary for the spindle S to retreat to a position where it does not hinder the movement of the plane table 4, the motor 7 is driven to rotate again and the second operation signal is sent to the variable speed drive sources 16, 26, 37. . Next, when the plane table 4 reaches the third position set in advance, the control mechanism 20 outputs a signal for stopping the variable-speed drive sources 16, 26, 37 and the motor 7 as in the case of the OFF state.

The embodiment of the invention is configured as described above, and the log 1 is cut as follows. As shown in FIG. 1, the cutting edge of the blade 2 and the support base 2 are actuated by an operation signal from a control mechanism 20 which has received a switch signal by a driver's manual input.
The plane table 4 is positioned such that the peripheral surfaces of the rolls 28 and 34 provided in the plane 2 are located at substantially equal distances around the spindle S, more precisely, on the Archimedean spiral curve in consideration of the thickness of the veneer. Then, the support base 22 and the support base 31 are moved to be on standby, and the motor 7 is driven to rotate the piercing roll 3 in the direction indicated by the arrow in FIG. Next, in response to an operation signal from the control mechanism 20 which also receives a switch signal manually input by the driver, the hydraulic cylinder is operated to bring the spindle S into contact with the both ends of the log 1 and support it, and then the variable speed drive source 18 is operated. Then, the spindle S is rotated. The rotation of the spindle S is measured by the rotation measuring device 17,
The first signal from the control mechanism 20 receiving the signal from the rotation measuring instrument 17
The variable speed drive sources 16, 26 and 37 are operated by the operation signal, and the amount of movement of the plane table 4, the support table 22 and the support table 31 toward the log 1 per rotation of the log 1 is constant. Moving.

Then, the piercing body 3a and the nose bar 10 of the piercing roll 3 are brought into contact with the peripheral surface of the log 1 on the side of the plane table 4, the roll 28 on the side of the support table 22, and the roll 34 on the side of the support table 31. 3. Power is supplied from the spindle S to the log 1 and is cut by the blade 2 to obtain a veneer T as shown in FIG. The roll 28 is driven and rotated by pressing against the rotating log 1, and as described above, the peripheral speed of the log 1 is obtained by the pulse counter 29. Based on this signal and the signal from the detector 15, the control mechanism 20 The second operation signal is calculated. At this point, the first operation signal is still transmitted to the variable speed drive sources 16, 26 and 37, and the second operation signal is not transmitted.

In this state, when cutting progresses and the signal from the detector 15 detects that the plane table 4 has reached the first position, the control mechanism 20 emits a buzzer sound. After hearing the buzzer sound, the driver visually looks at the log 1 being cut, separates the spindle S from the opening of the log 1, and removes the log 1 from the blade 2 of the plane table 4, the piercing roll 3 and the nose bar 10, and the rolls 28 and 34. The thickness of the veneer obtained in the case of cutting by supporting with the above becomes smaller than the set value, and it is determined whether or not there is a concave portion which becomes unusable or cannot be cut off on the peripheral surface of the log 1. Confirm. As shown in FIG. 7, when it is determined that the above-described concave portion 1a remains in the log 1,
The driver presses the determination switch 41. This judgment switch 4
Since the control mechanism 20 receiving the signal from 1 does not output a new operation signal, the plane table 4, the support table 22 and the support table 31 move in the same state as before the plane table 4 reached the first position. The cutting of the log 1 is continued. Next, when the detector 15 detects that the plane table 4 has reached the second position, the movement of the plane table 4, the support table 22 and the support table 31 is stopped by a signal from the control mechanism 20 receiving this signal. After a short delay, the rotation of the spindle S and the rotation of the piercing roll 3 stop. As a result, when the plane table 4 reaches the first position, the concave portion on the peripheral surface of the log 1 is removed when the plane table 4 moves to the second position while the log 1 is supported by the spindle S. When the plane table 4 reaches the second position, as shown in FIG. 8, the log 1 is substantially columnar.

Next, after the spindle S is separated from the raw wood 1 by a signal from the control mechanism 20 and the spindle S is retracted to a position where the movement of the plane table 4 is not hindered, the motor 7 is driven to rotate again and the plane signal is transmitted by the second operation signal. 4. The support table 22 and the support table 31 resume moving toward the log 1, the log 1 is rotated by the piercing roll 3, and the cutting by the cutting tool 4 is performed. In this cutting, the log 1 is cut into the cutting tool 2 of the plane table 4, the piercing roll 3, the nose bar 10, and the support table 22.
At this point, since there is almost no concave portion on the peripheral surface of the log 1 as described above, the center of rotation of the log 1 is maintained at a substantially fixed position and cut with the blade 4. There is no problem that the thickness of the veneer T becomes thinner than the set thickness. When the detector 15 detects that the cutting has further progressed and the plane table 4 has reached the third position shown in FIG. 4, the control mechanism 20 stops the variable speed drive sources 16, 26, 37 and the motor 7. A signal is issued and the plane table 4, the support table 22, and the support table 3
Cutting stops when 1 stops and the rotation of the piercing roll 3 stops. Next, the variable speed drive sources 16, 26, and 37 are operated by the driver's manual switch operation so that the plane table 4, the support table 22, and the support table 31 move backward in the direction opposite to the previous movement direction. The remaining raw wood 1 is dropped and eliminated, and a new raw wood is supplied and cut in the same manner.

On the other hand, the plane table 4 reaches the first position,
When a buzzer sound is output from the control mechanism 20 and the driver visually checks the log 1 being cut, and determines that the above-described concave portion does not remain as shown in FIG. Do not press 41. Therefore, the control mechanism 20 switches the first operation signal, which was initially used to operate the variable speed drive sources 16, 26, and 37, to the second operation signal, and similarly controls the plane table 4, the support table 22, and the support table 22. The movement of the platform 31 is continued. Next, in response to an operation signal from the control mechanism 20, the hydraulic cylinder is operated to separate the spindle S from the log 1 and start retreating. It takes a predetermined time for the spindle S to retreat to a position where it does not hinder the movement of the plane table 4. However, since the first position is set as described above, even if the plane table 4 continues to move, the spindle S Never hit. When the spindle S moves away from the log 1, the log 1
Is a blade 2, a piercing roll 3, and a nose bar 10 of a plane table 4.
And the roll 28 of the support base 22, but since the above-described concave portion does not remain in the raw wood 1, the center of rotation of the raw wood 1 is also kept almost at a fixed position, and the cutting is performed by the cutting tool 4. There is no problem that the thickness of the single veneer T becomes thinner than the set thickness.

Further cutting proceeds, and the plane table 4 shown in FIG.
Reaches the third position, the cutting from the plane table, the support table 22 and the support table 31 is stopped by the signal from the control mechanism 20 and the rotation of the piercing roll 3 is stopped. Next, by the driver's manual switch operation, the plane table 4, the support table 22 and the support table 31 are moved backward in the direction opposite to the previous movement direction, and the remaining log 1 is dropped and eliminated. Cutting is performed in the same manner.

Although the embodiment of the present invention has been described above, it may be modified as follows. 1. In the above-described embodiment, when the plane table 4 reaches the first position, the driver checks whether or not the above-described recess remains on the peripheral surface of the log 1 and responds to each case. Although the determination switch 41 is turned ON or OFF, the depression may be automatically detected by a single-plate detection member, and the operation of each member may be controlled by a control mechanism receiving the detection signal. That is, for example, the configuration is as follows. When there is a concave portion on the peripheral surface of the log 1, the cut veneer T has a hole Ta and a notch Tb as shown in FIG. 9 which is an explanatory plan view. Therefore, immediately after the veneer race, two belts 51 which are wound around a roll 50 driven to rotate in the direction of the arrow and a driven roll (not shown) and transport the veneer T are arranged. On the lower side in the T transport direction, there is provided a roll 52 that is driven to rotate in the direction of the arrow at the same peripheral speed as the belt 51. Above the roll 52, as shown in FIG. 10, which is an explanatory side view of FIG. 9, an arm 55 that has a roll 53 that is rotatable and driven by a lower end and that is rotatable about a shaft 54 is provided. When there is no veneer T under the roll 53, the roll 53 is positioned above the arm 55.
Is in contact with the roll 52 and in this state, the switch is turned on by being pushed by the upper end of the arm 55, and when the veneer T having a set thickness passes under the roll 53, the roll 53 is lifted and the arm 55 is moved as indicated by an arrow. The arm 55 is rotated counterclockwise by a predetermined amount, and the upper end of the arm 55 is separated.
A micro switch 56 serving as F is arranged. As shown in FIG. 9, for example, four sets of the veneer detecting members 57 provided in this way are arranged in a direction orthogonal to the veneer transport direction. This 4
O from the microswitch 56 of the set of single plate detecting members 57
The N and OFF signals are transmitted to the control mechanism 20, and when the plane table 4 reaches the first position in the control mechanism 20, the following judgment is made and a corresponding operation signal is output to cut the log 1.

That is, one of the logs 1 being cut at the first position.
In the time required for rotation, four micro switches 5
6 is transmitted to the control mechanism 20, which means that there is a recess on the peripheral surface of the log 1, but in the embodiment of the invention, the control mechanism 20 outputs a buzzer. Similarly to the case where a sound is output and the driver presses the determination switch 41, the control mechanism 20 outputs a signal for controlling the operation of each of the subsequent members, temporarily stops the plane table 4 at the second position,
Next, operations such as stopping the rotation of the spindle S and retracting the spindle S are performed to cut the log 1. on the other hand,
Similarly, in the time required for one rotation of the log 1 during cutting at the first position, all four micro switches 56
When the fact that the FF has been maintained is transmitted to the control mechanism 20,
This means that there is no recess on the peripheral surface of the log 1, but the control is performed in the same manner as in the embodiment of the present invention, in which a buzzer sounds from the control mechanism 20 and the driver does not press the determination switch 41. The mechanism 20 outputs a signal for controlling the subsequent operation of each member, performs operations such as retreating the spindle S without stopping the plane table 4, and cuts the log 1.

2. As a single-plate detection member, a light emitted from a light emitting diode is reflected only when an object is present at a set position, and the reflected light is detected by a light receiving element. May be used. That is, a moving table (not shown) that moves so as to always maintain a position at an equal distance from the peripheral surface of the cut and reduced diameter log is provided on a moving table (not shown) at a plurality of distances in a direction orthogonal to the moving direction of the moving table. A reflection type photoelectric switch may be provided so that when the plane table reaches the first position, the peripheral surface of the log is detected by the limited reflection type photoelectric switch, and the detected signal may be transmitted to the control mechanism 20. 3. In the embodiment of the invention, the spindle S is
Rolls 28 that move almost horizontally and rolls 34 that move almost vertically
However, the configuration may be as follows. That is, instead of the roll 28, the roll 28
As shown in FIG. 11, two rolls 61 and 62 each having a diameter of, for example, 120 mm, which are rotatable and rotatable in the same manner as in FIG.
The roll is provided so as to be at a remote position, and the roll is not used.
Similar to the roll 28, the peripheral surfaces of the two rolls 61 and 62 are positioned at substantially equidistant positions around the cutting edge of the blade 2 provided on the plane table 4 and the spindle S, strictly speaking, the thickness of the veneer. The robot is caused to stand by at a position on the spiral curve of Archimedes, and cutting is performed in the same manner as in the embodiment of the present invention. In addition, one of the rolls 61 and 62 is provided with a pulse counter 29 similarly to the roll 28 to measure the peripheral speed of the log 1,
When the spindle S is separated from the log 1, it is used as a signal for moving the plane table 4 and the support table 22 so that the thickness of the veneer to be cut is constant. In the embodiment of the present invention, as shown in FIG. 5, if the log 1 is cut to a smaller diameter, the roll 34 hinders the advance of the plane table 4. In the configuration using, as is clear from FIG.
62 does not hinder the movement of the plane table 4, and the log 1 can be cut until the diameter becomes smaller.

4. In the embodiment of the present invention, the piercing roll 3 is used for rotating the log 1 on the plane table 4. However, as shown in FIG. 11, a disk-shaped rotating body 6 having a smooth peripheral surface is used.
3 may be fixed to the rotating shaft 5 and the rotating force may be transmitted from the rotating body 63 to the log 1 by frictional force. 5. Similarly, as shown in FIG. 12, a roller bar 65 held by a holder 64 and rotated by a motor (not shown) may be used as a roll provided on the plane table 4 for rotating the log 1. 6. The plane table 4 may be provided with only a nose bar as a pressure bar, for example, without using the piercing roll 3, the rotating body 63, and the roller bar 65 for rotating the log 1. However, in this case, as a member for rotating the raw wood 1 when the spindle S is separated from the raw wood 1, a pulse counter 2 of a roll abutting on the raw wood 1, for example, the rolls 61 and 62.
The roll without 9 is rotated by a motor. In this case, a protrusion may be provided on the peripheral surface of the roll in the same manner as the piercing roll 3 in order to reliably transmit power to the log 1. 7. In the embodiment of the invention, a single spindle S is used. However, a plurality of single or double or more cylindrical spindles are provided around a central spindle to cope with cutting a log to a small diameter. Alternatively, a spindle having a structure in which the outer spindle is sequentially separated from the log and retreated may be used. As shown in FIG. 13 which is a side view, and FIG. 14 which is a front view of FIG. 13 as viewed from the left, for example, a single tip is provided around a center spindle 71 having a tip 71a at the tip. 7
In a so-called double spindle provided with a spindle 72 having 2a, the diameter of the spindle 71 is reduced to, for example, 4
The present invention can also be implemented with a veneer race in which the spindle 71 is set to 0 mm and the spindle 71 is kept in contact with the log 1 until the end of cutting in order to detect the rotation state of the log 1. That is, in such a veneer race, initially, as shown in FIG.
When the radius of the raw wood is reduced, the spindle 72 is separated from the raw wood 1 as shown in FIG.
And cut until the log becomes the minimum diameter in a range where the tip of the plane table does not hit the spindle 71. However, since the spindle 71 having a small diameter is easily bent by an external force as described above, and the rotation center of the log 1 cannot be kept at a fixed position, even in such a veneer race, as in the embodiment of the present invention, Rolls, for example, rolls 28 and 34, which come into contact with the peripheral surface of the first roller 1, are provided. In the above veneer race, the radius of the spindle 71 is replaced with the radius of the spindle S in the embodiment of the present invention to set the positions corresponding to the first position and the second position, and the third position is The minimum position where the tip of the plane table does not hit the spindle 71 is set. In the above veneer race, when the log 1 is cut and the plane table reaches the first position, the driver or the automatic detection is made as to whether or not the log 1 has the concave portion, similarly to the embodiment of the invention. If there is a concave portion, cutting is continued and the plane table is stopped at the second position, and only the spindle 72 is moved to the position shown in FIG.
As shown in FIG. 6, the wooden board 1 is moved away from the log 1 to a position where the movement of the plane table is not hindered.
Let only 1 be in contact. Next, the plane table is moved to perform cutting, and when the plane table reaches the third position, the plane table is stopped, and the cutting is completed. Also, when the plane table reaches the first position, if there is no concave portion, only the spindle 72 is separated from the log 1 while continuing cutting, and starts to retreat, and the plane table passes through the second position to reach the third position. And stop the plane table and finish the cutting. It should be noted that the spindle 71 may be rotated by applying power, or may be driven to rotate freely. The spindle may be of a type having a double spindle around the spindle 71. 8. In the embodiment of the present invention, the log 1
When the plane table 4 reaches the first position, the cutting of the log 1 is continued, and when the plane table 4 reaches the second position, the movement of the plane table 4, the support table 22, and the support table 31 is stopped. Although the rotation is stopped and the rotation of the spindle S and the rotation of the piercing roll are stopped with a slight delay, the rotation may be performed as follows. That is, when the concave portion 1a remains in the log 1, when the plane table 4 reaches the second position after passing through the first position, the movement of the plane table 4, the support table 22 and the support table 31 is stopped, The rotation of the roll is stopped, but the spindle S continues to rotate. In this state, the log 1 is substantially columnar, but after the spindle S rotating by the signal from the control mechanism 20 is separated from the log 1 and the spindle S is retracted to a position where it does not hinder the movement of the plane table 4, Then, the plane table 4, the support table 22, and the support table 31 are again moved toward the log, and cutting is performed in the same manner.

9. In the present invention, if the concave portion present on the peripheral surface of the log is relatively small, the spindle may be separated from the log and cut while supporting the log with an appropriate number of rolls and a plane table. Well, the point is that when cutting while supporting the log with a suitable number of rolls and a plane table, the thickness of the obtained veneer does not become smaller than the set value, and the recess does not make cutting impossible May be determined to have no recess. Therefore, the number of veneer detecting members 57 shown in FIGS. 9 and 10 can be increased in the direction orthogonal to the veneer transport direction, or the time during which one veneer detecting member 57 remains ON can be controlled by the control mechanism 2.
The size of the recess may be detected by measuring at 0 to determine whether or not the recess corresponds to the recess. 10. In the embodiment of the invention, the cutter 28 provided on the plane table 4 is provided with a roll 28 and a roll 34, which are examples of an appropriate number of rolls, regardless of the presence or absence of the concave portion on the peripheral surface of the raw wood from the start of the raw wood cutting. 2 and the peripheral surfaces of the rolls 28 and 34 provided on the support base 22 are kept on standby so that they are located at substantially equal distances around the spindle S. Thereafter, the rolls 28 and rolls are moved relative to the movement of the plane table. Although 34 was moved, the following may be performed. That is, at the start of cutting, the roll 28 and the roll 34 are kept away from the log, and only the plane table 4 is moved toward the log to perform cutting. At the latest, the plane table 4 being moved until the plane table 4 reaches the first position. And the peripheral surfaces of the rolls 28 and 34 provided on the support base 22 are moved to positions at substantially the same distance around the spindle S,
Thereafter, the roll 28 and the roll 34 may be moved relative to the movement of the plane table.

[0026]

As described above, according to the present invention, the thickness of the veneer obtained by cutting the log does not become smaller than the set value, and the cutting of the log 1 is performed even if there is a concave portion on the peripheral surface of the log. Can be performed well, and the yield is improved.

[Brief description of the drawings]

FIG. 1 is an explanatory side view of a conventional device.

FIG. 2 is an explanatory partial plan view of the dashed line AA in FIG.

FIG. 3 is an explanatory partial side view of the dashed line BB in FIG.

FIG. 4 is an operation explanatory view of the embodiment of the present invention.

FIG. 5 is a partial side view of the dashed-dotted line CC of FIG.

FIG. 6 is an operation explanatory view of the embodiment of the present invention.

FIG. 7 is an operation explanatory view of the embodiment of the present invention.

FIG. 8 is an operation explanatory view of the embodiment of the present invention.

FIG. 9 is an explanatory plan view of a modified example.

FIG. 10 is an explanatory side view of FIG. 9;

FIG. 11 is an explanatory side view of a modified example.

FIG. 12 is an explanatory side view of a modified example.

FIG. 13 is an explanatory side view of a modified example.

14 is an explanatory front view of FIG.

FIG. 15 is an operation explanatory view of a modified example.

FIG. 16 is an operation explanatory view of a modified example.

[Explanation of symbols]

 1... Log 2... Blade 3... Punching roll 4... Plane table 20... Control mechanism 28... Roll 34... Roll 57. ..Single plates

Claims (3)

[Claims] 1. A planer table equipped with a cutting tool is moved toward a base wood while cutting the base wood while the base wood rotating by a spindle abutted on both ends of the wood is continuously cut, and the plane base reaches the first position at the latest. By the time, an appropriate number of rolls are brought into contact with the peripheral surface of the raw wood, and then the rolls are moved following the peripheral surface of the raw wood having a smaller radius. When the plane table reaches the first position, the raw wood is removed. It is determined whether there is a recess not less than a predetermined value on the peripheral surface. If there is a recess not less than a predetermined value, the cutting is continued while the spindle is in contact with the opening. When the plane table reaches the second position, the plane table and the roll are rolled. After stopping the movement of the plane and moving the spindle away from the both ends, and retreating it to a position that does not hinder the progress of the plane table, start the movement of the plane table and roll again and cut the raw wood, and the plane table reaches the third position Then, move the plane table and the roll Stop and finish the cutting, if there is no more than a predetermined recess, start the retreat in the direction perpendicular to the direction of movement of the plane table by separating the spindle from the tip, and when the plane table reaches the third position, the plane table and the Log cutting method in veneer lace where the movement of the roll is stopped and the cutting is completed. In the above description, the first position, the second position, and the third position refer to the positions defined below. A first position: when the moving plane table reaches the first position, the spindle starts retreating in a direction perpendicular to the direction of movement of the plane table, away from the tip, and then the plane table moves to the position of the spindle; A position where the spindle retracts to a position where it does not hinder the movement of the plane table. 2nd position: A position on the log side from the first position, where the end of the plane table on the log side does not come into contact with the spindle in contact with the wood opening. Third position: a position where cutting of the raw wood ends. 2. A spindle having an operating member and capable of moving forward and backward, and a spindle reciprocally movable with respect to the spindle by the operating member.
A plane table with a blade, a plane table position detector that detects the position of the plane table with respect to the spindle, and an abutment surface that can be abutted and separated by the operating member and that has a radius that decreases with cutting after contact. An appropriate number of rolls that move following, a determining device that determines whether there is a concave portion that is equal to or greater than a predetermined amount on the peripheral surface of the raw wood, and a plane table that moves toward the raw wood supported by the spindle is at a first position at the latest. By the time it reaches, a suitable number of rolls are brought into contact with the peripheral surface of the log and moved following the peripheral surface of the log, and it is detected from the detection device that the plane table has reached the first position. When the signal having the concave portion is output from the determination device, no new operation signal is output, and when the detection device detects that the plane table has reached the second position, the movement of the plane table and the roll is performed. Stop and follow After the spindle is separated from the both ends and retracted to a position where it does not hinder the advance of the plane table, the movement of the plane table and the rolls is started again to cut the raw wood, and the detection device detects that the plane table has reached the third position. When the detection is detected by, the movement of the plane table and the roll is stopped. On the other hand, when it is detected from the detection device that the plane table has reached the first position, a signal without the concave portion is output from the determination device. Then, the spindle is moved away from the opening to start retreating in a direction perpendicular to the direction of movement of the plane table, and when the plane table reaches the third position, the operation members are controlled so as to stop the movement of the plane table and the roll. Veneer lace with control mechanism. In the above description, the first position, the second position, and the third position refer to the positions defined below. A first position: when the moving plane table reaches the first position, the spindle starts retreating in a direction perpendicular to the direction of movement of the plane table, away from the tip, and then when the plane table reaches the position of the spindle, A position where the spindle retracts to a position where it does not hinder the movement of the plane table. 2nd position: A position on the log side from the first position, where the end of the plane table on the log side does not come into contact with the spindle in contact with the wood opening. Third position: a position where cutting of the raw wood ends. 3. A central spindle, each of which has an actuating member, and is provided with a movable back and forth, and a spindle which is provided at least one layer outside the central spindle.
A plane table with a blade, a plane table position detector that detects the position of the plane table with respect to the spindle, and an abutment surface that can be abutted and separated by the operating member and that has a radius that decreases with cutting after contact. An appropriate number of rolls that follow and move, a determining device that determines the presence or absence of a recess that is equal to or greater than a predetermined amount on the peripheral surface of the log, and a plane table that moves toward the log supported by the spindle group is at least a first position. , A suitable number of rolls are brought into contact with the peripheral surface of the log and subsequently moved following the peripheral surface of the log, and the log is moved only by the central spindle and the single spindle. When the detection device detects that the plane table has reached the first position, and when a signal indicating the presence of the concave portion is output from the determination device, the respective members are similarly moved. Is the When the position has been reached is detected by the detection device, it stops movement of 鉋台 and roll then 1
After moving only the heavy spindle away from the two flutes and retreating to a position that would not hinder the progress of the plane table, the movement of the plane table and rolls was started again and the raw wood was cut, and the plane table reached the third position When detected by the detection device, the movement of the plane table and the roll is stopped. On the other hand, when it is detected from the detection device that the plane table has reached the first position, a signal indicating that there is no concave portion is transmitted from a determination device. When it is released, only the single spindle is separated from the tip and starts retreating in the direction orthogonal to the direction of movement of the plane table. Then, when the plane table reaches the third position, the movement of the plane table and the roll is stopped. Veneer lace equipped with a control mechanism for controlling each operating member. In the above description, the first position, the second position, and the third position refer to the positions defined below. First position: When the moving plane table reaches the first position, the single spindle starts retreating in a direction perpendicular to the direction of movement of the plane table, separating from the tip, and then the single plane spindle moves to the first position. A position where the single spindle retracts to a position where it does not hinder the movement of the plane table when it reaches a certain position. Second position: a position on the log side from the first position, where the tip of the plane table on the log side does not come into contact with the single spindle in contact with the tip. Third position: a position closer to the log than the second position, and a position where the log-side end of the plane table does not contact the center spindle in a state where it is in contact with the tip.