JPH0871822A - Air drill cooling device - Google Patents

Abstract

PURPOSE: To provide an air drill handy with weight increase suppressed to a minimum and having a cooling device sufficiently cooling a drill at the time of boring compound material such as CFRP and cooling compressed air, exhausted from the air drill, by powder refrigerant in a cooling tank. CONSTITUTION: An intake means 11 takes in exhaust air exhausted from a muffler 4 and leads it into a cooling tank 12. The exhaust air led into the cooling tank 12 is mixed with powder refrigerant 18 and cooled by the powder refrigerant 18, and the mixed air mixed in the cooling tank 12 is injected into a hood 8a. A drill 5 in the hood 8a is thereby cooled by the exhaust air and double-cooled since the heat is taken away by the powder refrigerant 18 adhering to the drill 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air drill cooling device, and more particularly to an air drill cooling device provided in an air drill for drilling a member to be processed by rotating the drill with supplied compressed air to cool the drill.

[0002]

2. Description of the Related Art Various types of cooling dust collectors for machine tools have been proposed so far. For example, JP-A-5
In JP-A-8-59746, a drill is surrounded by a hood, cutting oil mist is sprayed from four sides toward the center of the drill to cool the drill, and the inside of the hood is sucked to collect cutting oil mist and chips from dust collecting dust. A cooling dust collector for a machine tool for discharging is disclosed.

Further, the pressure foot of the printed board drilling machine disclosed in Japanese Patent Laid-Open No. 3-37113 is communicated with the chip suction device through a hose so that the inside of the pressure foot is in a negative pressure state. At the same time, the compressed air is jetted horizontally from near the tip of the pressure foot in the tangential direction of the drill. The compressed air expands in the pressure foot in a substantially adiabatic state, so that the temperature drops sharply to cool the drill, and at the same time, the chips are entrained and discharged to the chip suction device.

[0004]

On the other hand, a composite material such as a fiber reinforced plastic (hereinafter referred to as CFRP) is not only high in strength but also difficult to disperse the heat of processing into the material.
When making a hole in a composite material such as RP, the cutting heat is collected in the cutting tool, and the cutting edge is worn away, resulting in poor sharpness in a short time. When drilling a composite material such as CFRP, a method of cooling a drill by injecting cutting oil mist like a cooling dust collector of a conventional machine tool or a pressure foot of a conventional printed board drilling machine is used. The method of lowering the temperature by adiabatic expansion of compressed air has a problem that the drill is not sufficiently cooled. In the case of a conventional cooling dust collector for machine tools or a pressure foot for a printed board drilling machine, the weight increases because it is necessary to newly provide a means for introducing cutting oil mist and compressed air. There is a problem in that the weight becomes heavy and the handling becomes difficult when it is attached to an object to be held and used.

Therefore, an object of the present invention is to solve the problems of the above-mentioned prior art, to cool the drill sufficiently when drilling a composite material such as CFRP, and to reduce the weight of the air drill. To provide a device.

[0006]

In order to achieve the above object, the present invention comprises a hood for closing the periphery of a drill for drilling a member to be machined, and rotating the drill with supplied compressed air to process the workpiece. In the air drill that pierces the member and exhausts the supplied compressed air from the muffler, and discharges the cutting chips generated during piercing through the dust suction port formed in the hood, the air that takes in the exhaust air exhausted from the muffler Intake means, a powder refrigerant is stored therein, a cooling tank for mixing the exhaust air introduced through the air intake means and the powder refrigerant, and is communicated with the cooling tank and the hood, And an air supply pipe for supplying the mixed air mixed in the cooling tank into the hood.

[0007]

According to the present invention, the exhaust air exhausted from the muffler and lowered in temperature by the adiabatic expansion action is taken in by the air intake means and introduced into the cooling tank. The exhaust air introduced into the cooling tank is mixed with the powdery refrigerant and cooled by the vaporizing action of the powdery refrigerant. Then, the mixed air mixed with the powder refrigerant in the cooling tank is jetted into the hood. Therefore, the drill in the hood is cooled by the exhaust air whose temperature becomes low due to the adiabatic expansion effect and the vaporization effect, and at the same time, it is deprived of heat by the powder refrigerant attached to the drill. As a result, the drill is doubly cooled by the cooled exhaust air and the powdered refrigerant.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A cooling device for an air drill according to the present invention will be described below with reference to the drawings. In FIG. 1, an air drill generally designated by reference numeral 1 has a grip portion 2 a of an air drill body 2.
An air hose 3 is attached to the. Air hose 3
Is connected to an air supply source (not shown). Rotational force is applied to the drill 5 by the compressed air supplied from the air supply source. On the other hand, this compressed air is guided to the muffler 4 in the drill body 2 via the air hose 3 and is exhausted from the muffler 4. The drill 5 is provided at the tip of a spindle 6 (see FIG. 2), and the spindle 6 is rotatably supported by a spindle sleeve 6a. The spindle sleeve 6a is fixed to the drill body 2.

A piston sleeve 7 is supported by the air drill body 2 so as to extend and contract in parallel with the spindle sleeve 6a. A template foot 8 is fixed to the tip of the piston sleeve 7, and the template foot 8 is slidably supported by the spindle sleeve 6a through a hole 8b (see FIG. 2). As shown in FIG. 2, a hood portion 8a is formed on the template foot 8, and the spindle 6 and the drill 5 are fitted into the hood portion 8a through the hole 8b. A dust suction adapter 9 is fixed to the template foot 8 via screws 10, 10 and the like, and a dust suction port 9a of the dust suction adapter 9 is opened in the hood portion 8a. As a result, the cutting chips generated when drilling with the drill 5 are guided to the dust suction adapter 9 through the dust suction port 9a and are collected by the dust suction device (not shown) through the dust suction adapter 9. The dust suction adapter 9 is made of an aluminum material.

In FIG. 1, a cooling device for an air drill, generally designated by reference numeral 10, comprises an air intake means 11, a cooling tank 12 and an air supply pipe 13. The air intake means 11 has an air adapter 14, and the air adapter 14
Is made of synthetic resin such as plastic and is formed into a cylindrical shape. The air adapter 14 is fitted into the muffler 4 so as to cover the outer periphery of the muffler 4. A hole 14a is formed on the peripheral surface of the air adapter 14, and the muffler 4 exhausts air through the hole 14a.

An air cock 16 is attached to the peripheral surface of the air adapter 14 via a nut 15, and the air adapter 1
The inside of 4 and the air cock 16 are connected. Air cock 1
One end of an air intake pipe 17 is attached to the valve 6, and the other end of the air intake pipe 17 is attached to a left end portion of a cooling tank 12 described later. As a result, the muffler 4 in the air adapter 14 is communicated with the cooling tank 12 via the air cock 16 and the air intake pipe 17. The air intake tube 17 is a vinyl tube having a diameter of 8.0 mm and has a heat insulating effect.

The above-mentioned cooling tank 12 is formed of a transparent plastic material into a cylindrical shape, and a powder medium 18 such as cetyl alcohol is stored in the cooling tank 12.
As described above, since the cooling tank 12 is formed of the transparent plastic material, the remaining amount of the powder medium 18 can be easily known visually. The cooling tank 12 is laterally fixed to the upper portion of the air drill body 2 via a tank stopper 19.

That is, the tank stopper 19 is formed in a substantially U shape, and one end thereof is fixed to the upper portion of the air drill main body 2 with screws 20 and 20. In addition, the tank stopper 19
The cooling tank 12 has a screw 21a and a nut 2 on the outer circumference.
It is attached via 1b. As a result, the cooling tank 12 is laterally fixed to the upper portion of the air drill body 2 via the tank stopper 19 as described above.

An air supply pipe 1 is provided at the right end of the cooling tank 12.
The left end of the air supply pipe 3 is communicated with the air supply pipe 13, and the right end of the air supply pipe 13 is communicated with an injection port 9b formed in the dust suction adapter 9.
The injection port 9b opens in the hood portion 8a. Therefore, the cooling tank 12 is connected to the inside of the hood portion 8a via the air supply pipe 13. The air supply pipe 13 is
A vinyl tube with a diameter of 6.5 mm,
Has a heat insulating effect. Thus, the inner diameter (6.5 mm) of the air supply pipe 13 is equal to the inner diameter (8.0 m) of the air intake pipe 17.
m), the mixed air is compressed and injected into the hood portion 8a.

Next, the operation of the cooling device for an air drill according to the present invention constructed as described above will be described. First, the template foot 8 is brought into contact with the surface of the CFRP 30 (see FIG. 2) to seal the inside of the hood portion 8a, and the air drill 1 is operated to rotate the drill 5 with compressed air. This allows CFR
P30 is drilled with the drill 5. On the other hand, at the same time as the operation of the air drill 1, the compressed air is exhausted from the muffler 4 and the temperature is lowered by the adiabatic expansion action. This exhaust air is filled in the air adapter 14, and the pressure is adjusted appropriately by the air cock 16,
It is guided into the cooling tank 12 via the air intake pipe 17. The exhaust air guided into the cooling tank 12 is mixed with the powder medium 18 such as cetyl alcohol, and the temperature is lowered by the vaporizing action of the powder medium 18. Generally, the temperature of the compressed air supplied from an air supply source (not shown) is about 22 ° C, and the temperature of the exhaust air exhausted from the muffler 4 drops to about 16 ° C due to the adiabatic expansion action. Then, the temperature of the mixed air cooled in the cooling tank 12 is lowered to about 10 ° C. by vaporization.

The mixed air of the exhaust air cooled in the cooling tank 12 and the powdery refrigerant 18 is jetted from the jet port 9b toward the drill 5 through the air supply pipe 13 into the hood portion 8a. As a result, in the hood 8a, the exhaust air whose temperature is lowered by the two functions of the adiabatic expansion effect and the vaporizing effect of the powder medium 18 and the powder medium 18 mixed with the exhaust air
Is filled. Then, the powder refrigerant 18 adheres to the drill 5 and absorbs heat to cool the drill 5. Therefore, the drill 5 filled with the processing heat has the exhaust air and the powdered refrigerant 18
And double cooled.

The mixed air filled in the hood portion 8a is guided to the dust collecting adapter 9 through the dust collecting port 9a together with the cutting chips generated when the drill 5 is used for drilling, and is illustrated through the dust collecting adapter 9. Not collected in the dust collector. This ensures the safety of the human body and work environment.

[0018]

As is apparent from the above description, according to the air drill cooling device of the present invention, the exhaust air exhausted from the muffler and having its temperature lowered by the adiabatic expansion action is taken in by the air intake means. Guide it into the cooling tank. The exhaust air introduced into the cooling tank is mixed with the powdery refrigerant and cooled by the vaporizing action of the powdery refrigerant. Then, the mixed air mixed with the powder refrigerant in the cooling tank is jetted into the hood. Therefore, the drill in the hood is cooled by the exhaust air whose temperature becomes low due to the adiabatic expansion effect and the vaporization effect, and at the same time, it is deprived of heat by the powder refrigerant attached to the drill.
As a result, the drill is doubly cooled by the cooled exhaust air and the powdered refrigerant.

Therefore, the drill can be sufficiently cooled when boring a composite material such as CFRP. This allows
The life of the drill is C compared to the case of the conventional air drill.
There was a 75% extension upon perforation of the FRP. Further, since the compressed air discharged from the air drill is cooled by the powdered refrigerant in the cooling tank, the weight increase of the cooling tank can be minimized, and the air drill with a cooling device which is easy to use can be provided.

[Brief description of drawings]

FIG. 1 is a perspective view showing a state in which an air drill cooling device according to the present invention is attached to an air drill.

FIG. 2 is an enlarged view of a main part of a cooling device for an air drill according to the present invention.

FIG. 3 is a vertical cross section taken along the line AA showing a state of being cut in the vertical direction along the cross section AA in FIG.

[Explanation of symbols]

 1 Air Drill 4 Muffler 5 Drill 8a Hood 9a Dust Intake Port 9b Jet Port 10 Screw 11 Compressed Air Intake Means 12 Cooling Tank 13 Air Supply Pipe 18 Cooling Medium 30 CFRP (Workpiece)

Claims (3)

[Claims] 1. A hood for closing the periphery of a drill for piercing a work member, rotating the drill with the supplied compressed air to pierce the work member and exhausting the supplied compressed air from a muffler, In an air drill that discharges cutting chips generated during drilling through a dust suction port formed in a hood, an air intake means that takes in exhaust air exhausted from the muffler, and a powder refrigerant is stored inside the air intake means, and the air intake is performed. A cooling tank for mixing the exhaust air introduced through the means with the powdered refrigerant, and a cooling air which is in communication with the cooling tank and also in the hood, and which is mixed air in the cooling tank is supplied into the hood. An air drill cooling device comprising: an air supply pipe. 2. The cooling device for an air drill according to claim 1, wherein the air supply pipe injects the mixed air to a cutting edge portion of the drill. 3. The cooling device for an air drill according to claim 1, wherein the air intake pipe of the air intake means is set to have an inner diameter larger than that of the air supply pipe.