JPS6334884Y2 - - Google Patents

Description

[Detailed description of the invention] <Industrial field of application> The present invention consists of a surface plate having a cutting edge and a cutting tool facing each other, and a material feeding device that are disposed opposite to each other via a material feeding path. In a reciprocating wood slicer in which the material device is equipped with a material conveying belt that reciprocates by a reversible material feed motor, the material feeding surface supplies lubricant to the surface plate in order to allow the processed material to travel smoothly without resistance. Regarding lubrication devices.

<Prior art> As disclosed in Utility Model Application Publication No. 47-42079, this type of lubricating device has an automatic oil supply device installed above the surface plate and allows lubricating oil to flow down from the oil supply device to the surface plate. There is something I did. However, this configuration has the disadvantage that lubricating oil is supplied even when the workpiece is not traveling, resulting in excessive consumption.

In addition, when such a configuration is applied to a reciprocating wood slicer, lubricating fluid is continuously supplied onto the surface plate when the workpiece is traveling back and forth, and when the material is being transported forward, the fluid is scraped off as it travels. Since the blade side is higher than the blade mouth, the liquid was forced into the opening between the blade mouth and the blade, and most of it was wasted.

The object of the present invention is to provide a material feeding surface lubrication device that can eliminate the above-mentioned drawbacks.

<Means for solving the problem> The present invention has a liquid supply port that supplies lubricating liquid to the surface plate surface, and a liquid supply port that is provided beside the material feeding path to detect the passage of the processed material and reversibly feed the material. A workpiece detection means that switches the driving direction of the motor, and a control system that supplies lubricant to the liquid supply port side when the workpiece is being fed backwards, and stops the supply when the workpiece is being fed forward, as the workpiece detection means detects the passage of the workpiece. The device is characterized by comprising a valve.

<Operation> By controlling the supply of the cleaning liquid using the control valve, the lubricating liquid is supplied to the surface plate only when the workpiece is fed back. Therefore, the amount of lubricant consumed is halved.

Furthermore, during reverse feeding, since the blade side is higher than the cutting edge, it is difficult for the lubricating liquid to be guided to the opening, and as the workpiece travels, the lubricating liquid is swept toward the entrance side of the surface plate. The lubricating fluid that has been swept away will be effectively used in the next normal feeding process.

<Example> An example of the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows an example of a vertical slicer, in which reference numeral 1 denotes a base, and columns 2, erected on one side of the base,
2, a material feeding device 6 comprising an endless material feeding belt 3 wrapped around a driving roll 4 and a driven roll 5 is supported at an upper position. The drive roll 4 is driven and controlled by a reversible material motor M. Further, on the inner surface of the lower running portion of the endless material conveying belt 3, a large number of pressure rolls 7 are disposed along the running direction thereof and are urged downward by an air cylinder, a spring, or the like. Furthermore, the material feeding device 6 is vertically threaded with lifting screws 6a, 6a, and can be moved up and down by rotation of the screws. In addition, the lifting screw 6
a, 6a are rotationally controlled by a lifting motor (not shown).

A rear surface plate 8 on which a cutter 9 is mounted is fixed on the other side of the base 1, and a movable table 11 having an inclined surface 10 on its upper surface that slopes forward is mounted on the front part of the surface plate 8. be placed. The movable table 11 can be moved in the front-back direction by screwing a screw rod 12 supported on the front surface of the base 1 in the front-back direction and rotating the handle of the screw rod 12.

Further, on the moving table 11, there is provided an intervening table 1 having an inclined surface 13 formed on the lower surface with the same angle of inclination as the inclined surface 10.
4 will be on board. A front surface plate 15 is mounted on the horizontal upper surface of the intervening stand 14, and the blade mouth 16 is tilted at the same angle as the blade 9 on the surface plate 15.
It is provided through an opening o in front of the (see Fig. 2). A screw rod 17 supported on the lower front surface of the front surface plate 15 is screwed in the front-rear direction to the interposed stand 14,
By rotating the handle of the screw rod 17, the surface plate 1
5, the upper surface of the surface plate 15 can be raised and lowered by moving the interposition stand 14 in the front and back direction.
As the upper surface of the intervening stand 14 moves up and down, the blade mouth 16 moves up and down relative to the cutter 9.

As shown in FIG. 2, a large number of liquid supply ports 20 are arranged on the surface plates 8 and 15 at regular intervals.

The structure of the liquid supply port 20 will be explained with reference to FIG.
1 from below, and a mouth body 24 is screwed from above into a screw groove 23 provided at the center of the upper part. The mouth body 24 has a large diameter liquid chamber 25 whose lower surface is open and communicates with a supply pipe 27 screwed from below of the mounting body 22 in the screwed state.
and an upper small-diameter outlet 26 communicating with the liquid chamber 25.
It is composed of.

The liquid supply port 20 may be provided only on the rear surface plate 8.

The supply pipe 27 is connected to an air pump 28, and the air pump 28 is controlled to open and close with an air source 30 by a three-way solenoid valve (control valve) 29. That is, when the three-way solenoid valve 29 is switched to the open state, the air pump 28 is driven and the tank t
The lubricating liquid inside is supplied from the liquid supply port 20 to the surfaces of the surface plates 8 and 15.

As another means of the control valve, instead of the three-way solenoid valve 29, a solenoid valve that directly opens and closes the lubricating fluid may be installed in the supply pipe 27.

Further, as shown in FIG. 2, a discharge groove 31 is provided around the surface plate 8, 15, and a discharge hole 32 is formed at a suitable position in the discharge groove 31. The discharge groove path 3
Instead of 1, a receiving gutter may be provided on the peripheral side surface of the surface plates 8 and 15.

One of the front parts of the pressure roll 7 is a detection roll 7a, and as shown in FIG. 1, an elevating shaft 36 whose lower end is fixed to a shaft support piece 34 projects upward from a support plate 37, and a screw is attached to the upper end of the elevating shaft 36. At the same time, a spring 39 is inserted between the shaft support piece 38 and the support plate 37.
is attached to the detection roll 7 due to the elasticity of the spring 39.
A is urged toward the material feeding path side to be inscribed in the endless material feeding belt 6, and a limit switch LS ₁ is provided below the flanged nut 38. This limit switch
LS ₁ engages and contacts the flanged nut 38 in the normal state and is in the on state (non-detection state).

Further, one of the rear portions of the pressure rolls 7 is also a detection roll 7b having the same structure as described above, and a limit switch LS ₂ which is operated by contacting and separating from the flanged nut 38 is disposed above the detection roll 7b.

The limit switches LS ₁ and LS ₂ constitute a workpiece detection means for switching the driving direction of the reversible material feed motor M, and the opening and closing of the three-way solenoid valve 29 is controlled by opening and closing of the limit switches LS ₁ and LS ₂ , and processing is performed. The lubricating liquid is allowed to flow out from the liquid supply port 20 only when the material w is fed back.

Its operation will be explained below.

When the reversible material motor M rotates forward, the endless material belt 3 runs and the workpiece w is fed forward, and the lower surface of the workpiece w is vertically cut by the blade 9 to form an opening between the blade 9 and the cutting edge 16. The projecting plate is discharged downward from o.

Further, when the workpiece w is fed forward, the detection roll 7b is raised at the front end of the workpiece w, the limit switch LS ₂ is disengaged from the flanged nut 38 and becomes an OFF state (detection state), and then the rear end of the workpiece w It turns back on when it passes. Due to this off-on conversion of the limit switch _LS2 , the driving of the material feeding motor M is stopped, and the workpiece w stops traveling.

In addition, in synchronization with the stoppage of the running, the lifting motor is driven, the material feeding device is raised by a predetermined amount, and the endless material feeding belt 3
contacts the upper surface of the workpiece w with an appropriate pressure that allows for reverse feeding.

Then, in synchronization with the completion of the rise by a predetermined amount, the reversible feed material motor M is driven in reverse, the workpiece w is fed backward, and the solenoid valve 29 is switched to cause the lubricant to flow out to the liquid supply port 20. Ru.

During this reverse feeding, the lubricating liquid flows out from the flow path 38 to the surfaces of the surface plates 8 and 15 due to the appropriate hydraulic pressure in the liquid chamber 25, and the lower surface of the workpiece w is wetted by the lubricating liquid.

When the front end of the workpiece w rises above the detection roll 7a and descends as it passes the rear end due to the reverse feeding, the limit switch LS ₁ disengages and re-engages with the flanged nut 38, causing an off-on conversion. As a result, the three-way solenoid valve 29 is switched to the closing direction due to an operation mode similar to that of the limit switch LS ₂ , and the flow of lubricating fluid from the liquid supply port 20 is stopped, and the material feeding device 6 is lowered and the reversible feeding material is stopped. Normal rotation of the motor M occurs sequentially. For this reason, no lubricating fluid is supplied during forward feeding of the workpiece w.

In the embodiment described above, the mouth body 24 is removably screwed into the screw groove 23 of the mounting body 22. Therefore, if cutting debris accumulates in the liquid chamber 25,
The mouth body 24 can be easily removed by rotating the mouth body 24 using the detachable hole 24a formed on the upper surface thereof, making cleaning, parts replacement, etc. easy.

FIG. 4 shows an injection nozzle 40 installed on the side of the surface plates 8, 15 instead of the liquid supply port 20 in the above configuration.
A plurality of (liquid supply ports) are arranged, and even with such a configuration, similar effects can be achieved. The injection nozzle 40 is provided on both sides or one side of the surface plates 8 and 15. Alternatively, it may be provided only on the side of the surface plate 8.

FIG. 5 shows the present invention with a surface plate 50 and a material feeding device 51.
This is applied to a reciprocating woodworking slicer that is installed oppositely on the left and right sides of the material feed path. In this case,
By arranging the injection nozzle 52 (liquid supply port) on the surface plate 50 so that its mouth end faces the surface plate surface, liquid can be jetted from the mouth end when the workpiece w is fed back. Then, it will run down the surface of the surface plate 50,
The lubricant can flow down and wet the surface of the surface plate.

Of course, as in the above embodiment, the liquid supply port 20
may be formed in large numbers on the surface plate surface.

<Effects of the invention> As clarified by the explanation of the above embodiment, the present invention supplies lubricant to the surface plate only when the workpiece w is fed back, so the consumption of lubricant is reduced. is halved. Furthermore, since the supply of lubricating fluid is stopped during forward feeding, the fluid is not scraped off as the lubricating fluid moves and is not guided and discharged between the cutting tool and the cutting edge. That is, as the workpiece w is transported backward, the lubricating fluid is swept toward the inlet side of the surface plate, and the swept away lubricating fluid is used in the next forward transport step.

Therefore, there are excellent effects such as less consumption of lubricating fluid and more effective use of the lubricating fluid.

[Brief explanation of the drawing]

The attached drawings show one embodiment of the present invention, in which FIG. 1 is a side view of a vertical slicer, and FIG. 2 is a side view of a vertical slicer.
3 is a longitudinal sectional view showing the liquid supply port 20, and FIGS. 4 and 5 are front views of main parts of other embodiments. 3; Endless material conveying belt, 6; Material conveying device, 9; Cutting tool, 8; Rear surface plate, 16; Blade opening, 15; Front surface plate, 20; Liquid supply port, 29; Three-way solenoid valve (control valve) , 40; injection nozzle; 50; surface plate; 51; material feeding device; 52; injection nozzle; LS ₁ , LS ₂ ; limit switch; M; reversible travel motor.

Claims (1)

[Scope of Claim for Utility Model Registration] 1. A surface plate having a cutting edge and a cutter facing each other, and a material feeding device are disposed opposite to each other through a material feeding path, and the material feeding device is provided with a reversible material feeding motor. In a woodworking slicer equipped with a reciprocating material feeding belt, there is a liquid supply port that supplies lubricating liquid to the surface plate surface, and a liquid supply port provided beside the material feeding path to detect the passage of the processed material and reversibly feed the material. A workpiece detection means that switches the driving direction of the motor, and a control system that supplies lubricant to the liquid supply port side when the workpiece is being fed backwards, and stops the supply when the workpiece is being fed forward, as the workpiece detection means detects the passage of the workpiece. A material feeding surface lubrication device in a reciprocating woodworking slicer, characterized by comprising a valve. 2. The material feeding surface lubrication device for a reciprocating woodworking slicer according to claim 1, wherein a plurality of the liquid supply ports are embedded in the surface plate surface. 3. In a reciprocating wood slicer in which a surface plate and a material feeding device are arranged vertically opposite each other, the liquid supply port is arranged near the surface of the surface plate,
A lubricating device for a material feeding surface in a reciprocating woodworking slicer according to claim 1, characterized in that the device comprises an injection nozzle whose injection port is directed toward the surface of the surface plate. 4. In a reciprocating woodworking slicer in which a surface plate and a material feeding device are arranged opposite to each other on the left and right sides of a material feeding path, the liquid supply port is arranged at the upper part of the surface plate surface,
A lubricating device for a feeding surface of a reciprocating woodworking slicer according to claim 1, characterized in that the device comprises an injection nozzle whose injection port is directed toward the surface of the surface plate.