JPS6111765B2 - - Google Patents

Description

Detailed Description of the Invention (Object of the Invention) The present invention aims to mechanically accurately detect the retraction stop position of the tool post in accordance with the log diameter. This invention relates to a stop position detection device.

(Prior Art) Conventionally, the retraction stop position of a veneer lace turret has been determined by determining the maximum diameter of the raw wood through visual judgment by the operator. For safety, the turret is moved back far compared to the diameter of the log, and during cutting, the turret is fed at high speed until just before cutting, and then the turret is switched to step feed to cut the log. was. Therefore, the amount of retraction of the turret and the amount of high-speed forward feed of the turret that is not involved in cutting raw wood are increased, the operating time of the veneer race is shortened, and the forward movement of the turret can quickly change from high-speed feed to step feed. There were some problems, such as the need for a mechanism to convert to

Furthermore, since the amount of retraction of the tool post, the amount of high-speed forward feed, and the switching position for step feed are determined by the operator's visual judgment, an error in judgment may result in the amount of retraction of the tool post being too small compared to the diameter of the log. Alternatively, the amount of high-speed forward feed was too large, and it could not be said that there would be no possibility of the raw wood coming into contact with or colliding with the cutter.

Due to the above-mentioned circumstances, worker fatigue increases, danger is involved, and automatic operation of veneer lace by unmanned operation is difficult.

(Structure of the Invention) The present invention has been made against the background of the above-mentioned prior art, and its gist is that a light beam, a laser beam, an ultrasonic wave, etc., which are attached to the rolling surface of raw wood so as to be able to rise and fall freely in the vertical direction, The maximum diameter of the log is detected by the log maximum diameter detection means using the log maximum diameter detection means, and the raising and lowering of the log maximum diameter detecting means and the advance and retreat of the tool post are such that the ratio of the amount of elevation and the amount of advance and retreat is 2:1. synchronize with each other,
The log maximum diameter detection means transmits a signal that detects the maximum diameter of the log to the tool rest, and the tool rest is moved back to an appropriate position corresponding to the diameter of the log and stopped.

Embodiments of the present invention will be specifically described below with reference to the accompanying drawings.

In Figures 1 and 2, veneer lace L
A carry-in conveyor 1 for carrying in logs W is installed horizontally in front of the
A pair of bridge members 2 are spanned between and the veneer lace L with a slight forward inclination. At the front end of this bridge material 2, the log W that has rolled on the bridge material 2 is temporarily held, and the log W that is rotated and held around the shaft 3 is held between both chucks C of the veneer race L. A pair of raw wood inputting members 4 are provided for inputting logs. Front surface 5a of one headstock 5 of veneer race L
A phototube box 6 is attached perpendicularly to the bridge material 2.

In addition, in FIGS. 1 to 4, two guide rods 9 are supported by an upper plate 7 and a lower plate 8 fixed to the top and bottom of the photocell box 6. An elevating body 11 is slidably mounted via a bearing 10,
A phototube 12 serving as both light emitting and light receiving means is integrally attached to this elevating body 11 as means for detecting the maximum diameter of logs. A guide pulley 14 is attached to the center of the upper plate 7 via a shaft 13. Also, the first
As shown in the drawings and FIG. 5, another guide pulley 15 is attached substantially below the guide pulley 14 on the side surface 5b of the headstock 5, and the lower end of the tool rest 16 on the side surface 5b of the headstock 5 is advanced. Another guide pulley 17 is attached in front of the end position, and an adjustment bolt 19 is screwed into a bracket 18 attached diagonally below the guide pulley 17 so as to be freely movable in the forward and backward direction of the tool rest 16.

On the other hand, the tool rest 16 is configured to be able to move forward and backward in a direction inclined at a predetermined angle with respect to the horizontal, and a movable pulley is attached to the lower end surface 16a of the tool rest 16 via a bracket 20, which does not impede the movement of the tool rest 16 back and forth. 2
1 is attached. Also, one end of the rope 22 is fixed to the elevating body 11, this rope 22 is sequentially hung on the guide pulleys 14, 15, 17 and the movable pulley 21, and the other end of the rope 22 is attached to the tip of the adjustment bolt 19. It is fixed and the turret 1
6 retreats, the rope 22 is gradually pulled, and the elevating body 11 to which the phototube 12 is attached rises, and when the tool rest 16 moves forward, the elevating body 11 descends while pulling the rope 22 by its own weight. There is.

As is clear from the above description, the ratio between the amount of elevation _L1 of the phototube 12, which is the means for detecting the maximum diameter of logs, and the amount of advancement and retreat _L2 of the tool rest 16 is 2:1.
Therefore, when the phototube 12, which is the log maximum diameter detection means, rises and detects the maximum diameter D of the log W, the tool rest 16 moves back by half the amount of rise of the phototube 12 and stops.

Here, when the log W is put between both chucks C, the log W is attached to the cutter 23 attached to the tool rest 16.
When the phototube 12, which is the log maximum diameter detection means, detects the maximum diameter of the log W and the tool post 16 stops, the cutter 23 attached to the tool post 16 and the log W are prevented from coming into contact with or colliding with each other. The length of the rope 22 is adjusted so that a predetermined gap t is formed between the two, and the size of the gap t can be freely adjusted by moving the adjustment bolt 19 forward and backward.

Further, in Fig. 1, 24 is a roller that serves both for centering and for driving the outer circumference of the raw wood W inserted between the chucks C, and the three rollers 24 synchronize with each other to move the log W into the center of the main shaft. It is configured so that it can be approached and separated.

In addition, in FIG. 2, 25 is a reflector plate for reflecting the light beam emitted from the phototube 12, and the line segment connecting this reflector plate 25 and the phototube 12 is aligned with the axis of the log W. It is tilted at a predetermined angle, so even if the diameter of the log W to be input changes, the log W is always
The maximum diameter of the diameter can be detected.

Further, in the above embodiment, the phototube 12 that emits and receives light and the reflector 25 constitute the maximum diameter detection means for logs, but the maximum diameter detection means for logs may also be constituted by the phototube for projecting light and the phototube for receiving light. Furthermore, the log maximum diameter detection means may be configured with a transmitter and a receiver that utilize laser beams or ultrasonic waves. Furthermore, when the tool post 16 moves forward, the elevating body 11 descends due to its own weight and the rope 22 is pulled, but if the resistance of the rope 22 is large and the rope 22 cannot be pulled by the own weight of the elevating body 11 alone, ,
For example, the elevating body 11 and the lower plate 8 may be connected by a tension spring (not shown), and the elevating body 11 may be forcibly lowered by the tensile force of the tension spring to pull the rope 22.

Note that 26 in the figure indicates a window provided in the phototube box 6.

(Action of the invention) Next, the action of the present invention will be explained.
In the figures and FIG. 2, when the logs W are transferred from the carry-in conveyor 1 to the bridge material 2, the logs W roll and move to the log inputting member 4 as shown by the two-dot chain line in FIG.
is temporarily held. In this state, the tool rest 16 is stopped at the forward end position as shown by the two-dot chain line.

After that, when the drive device (not shown) of the tool rest 16 is started and the tool rest 16 is moved backward, the movable pulley 2
The rope 22 is pulled along the retreat of the phototube 1, and the elevating body 11 to which the phototube 12 is attached rises in a direction perpendicular to the rolling surface of the log W, and the light rays emitted from the phototube 12 are reflected by the reflection plate 25. When the light is received, the maximum diameter D of the raw wood W is detected, and this signal is transmitted to the drive device of the tool post 16, causing the tool post 16 to move backward and stop at the position shown by the solid line. here,
The retraction amount L ₂ of the tool rest 16 is 1/2 of the rise amount L ₁ of the phototube 12, which is the means for detecting the maximum diameter of the log, and the tool rest 16 retreats by approximately 1/2 of the diameter D of the log W and then stops. do.

Then, while keeping the three rollers 24 separated from the axis of the main shaft, the log input member 4 is rotated in the direction of arrow P to input the log W between both chucks C of the veneer race L, and then Later, when the three rollers 24 are moved closer to the axis of the main shaft to hold the log W, the log W is centered. In this state, as described above, a predetermined gap t is formed between the cutter 23 of the tool rest 16 and the log W held between the chucks C.

Next, both end surfaces of the raw wood W held by the three rollers 24 are held between the chucks C, and then the tool rest 16
The log W is cut by activating the drive device and moving it forward. When the tool rest 16 moves forward, the elevating body 11 to which the phototube 12 is attached descends while pulling the rope 22 by its own weight.

(Effects of the Invention) The present invention allows the ratio of the vertical movement of the log maximum diameter detection means and the movement of the tool post to be 2:1.
Since it is synchronized so that the retraction stop position of the tool rest is accurately detected mechanically in accordance with the diameter of the log, without relying on visual judgment as in the past,
It becomes possible to move the tool rest back to an appropriate position and stop it. For this reason, the amount of advance of the tool post that is not related to cutting can be minimized, and there is no need to feed the tool post at high speed until just before cutting and then switch to step feed as in the conventional method. It becomes possible to move the table forward.

In addition, the retraction stop position of the tool post can be accurately detected mechanically in accordance with the diameter of the log, so if the amount of retraction of the tool post is too small, the log may come into contact with the cutter when loading the log. can definitely avoid collisions.

Furthermore, the machine can accurately detect the retraction stop position of the tool post in accordance with the diameter of the log without relying on the visual judgment of the worker, and the tool rest can be moved back to the appropriate position and stopped, reducing worker fatigue. This will reduce the amount of stress and improve safety, and furthermore, it will become possible to operate the veneer lace automatically by unmanned operation.

[Brief explanation of the drawing]

FIG. 1 is a side view showing only the main parts of a veneer race L equipped with a tool post retraction position detection device according to the present invention, FIG. 2 is a plan view, and FIG.
The plan view of the photocell box 6, FIG. 4, is also a front view,
FIG. 5 is an enlarged view taken along the line X--X in FIG. 1. (Explanation of symbols of main parts), 2...Bridge material, 5...
... Headstock, 6 ... Photocell box, 11 ... Lifting body, 1
2...Phototube (log maximum diameter detection means), 14,1
5, 17... Guide pulley, 21... Moving pulley, 22... Rope, 25... Reflector, W... Log.

Claims (1)

[Claims] 1. A means for detecting the maximum diameter of logs using light beams, laser beams, ultrasonic waves, etc. is attached to the front of the headstock of the veneer race so that it can move up and down in a direction perpendicular to the rolling surface of the logs, so that it will not interfere with the movement of the tool rest. At the same time, a plurality of guide pulleys for guiding the rope are attached to required locations on the side of the headstock, and one end of the rope is fixed to the log maximum diameter detection means. At the same time, the rope is hung around each of the guide pulleys and the moving pulley, and the other end is fixed near the forward end position of the tool post, and the elevation of the maximum log diameter detection means and the advance and retreat of the tool post are determined by the amount of elevation. A device for detecting a backward stop position of a tool post in a veneer race, characterized in that the backward stop position of a tool post in a veneer race is detected by synchronizing each other so that the ratio of the forward and backward movement is 2:1, and detects the backward stop position of the tool rest corresponding to the diameter of the log. .