JPH0218871Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to a fluid conduit, particularly a coolant conduit used when machining a workpiece with a machine tool.

(Prior Art) During machining with a machine tool, a conduit for supplying coolant toward the cutting edge of the tool is attached to the machine tool.

Conventionally, flexible metal tubes have been used as coolant conduits. The conduit, which is a flexible metal tube attached to the machine tool, is used with appropriate curvature so that it does not interfere with the operator during machining and to direct the coolant to the correct location.

However, since the curved flexible metal tube is made of a spirally wound round wire made of spring steel, the degree of curvature gradually decreases over time. For this reason, the degree of curvature must be corrected during processing, resulting in a problem that the efficiency of processing operations is reduced.

Furthermore, depending on the size and diameter of the workpiece, it is desirable to lengthen or shorten the length of the conduit, but in the conventional conduit, the length can be adjusted substantially. Can not do it.

(Purpose of the invention) An object of the invention is to provide a conduit that can maintain a once set degree of curvature for a long period of time.

(Structure of the invention) The conduit according to the invention consists of a plurality of interconnected units each consisting of a male part and a female part, each of which is integrally formed of an elastic material and through which a passage passes through the center, and a plurality of interconnected units made of an elastic material. and a nozzle connected to the unit located at the leading edge, the male part of one of the two adjacent units forming a spherical pair and the female part of the other unit, and The nozzle has a connecting portion forming a spherical pair with the male portion of the unit located at the most distal end, and the radius of the spherical surface of the male portion of the unit is larger than the radius of the spherical surface of the female portion of the unit that is in contact with the spherical surface, and The radius of the spherical surface of the male part of the unit is larger than the radius of the spherical surface of the connection part of the nozzle that is in contact with the spherical surface.

(Operations and effects of the invention) According to the invention, each unit and the nozzle are each made of an elastic material, and the spherical surface of the male part is replaced by the spherical surface of the male part and the female part, which form a pair of spherical surfaces. The diameter is set larger than the spherical surface of
Moreover, since the diameter is set to be larger than the spherical surface of the connecting portion that is a spherical pair with the male portion, the male portion and the female portion are elastically deformed to each other in the radial direction of these spherical surfaces and are in close contact with each other on these spherical surfaces. Similarly, the male part and the connecting part also elastically deform each other in the radial direction of their spherical surfaces and come into close contact with each other on their spherical surfaces. This maintains the liquid tightness between the units and between the units and the nozzle, that is, the liquid tightness of the conduit. The intersection angle between the axes and the axes of the nozzle, ie the connection angle, is maintained for a long time.

Furthermore, even after the conduit has been installed on the machine tool, an appropriate number of units can be added or removed, thereby making it easy to change the length of the conduit as required.

(Embodiments) The features of the present invention will become clearer from the following description of the illustrated embodiments.

As shown in FIGS. 1 and 2, a conduit 10 according to the present invention includes a plurality of units 12 connected to each other.

Each unit 12, as shown in FIGS. 3-5, consists of an integrally formed plastic male part 14 and female part 16, with a passageway 18 passing through the center thereof. Examples of facultative plastic materials include acetal.

The male portion 14 and the female portion 16 have a common axis.
The male part 14 has a spherical surface 14 that is formed when a circular arc having a center on the axis is rotated around the axis.
a and the cylindrical surface 1 extending from the spherical surface toward the female part 16
4b. On the other hand, the diameter of the female part 16 is from the open end surface 16a to the male part 1.
It has an outer circumferential surface that gradually increases toward 4 and then gradually decreases to continue with the cylindrical surface 14b of the male portion 14. The outer diameters of the male portion 14 and the female portion 16 at their boundaries are the same, and the maximum outer diameter of the female portion 16 is greater than the maximum outer diameter of the male portion 14.

The inner peripheral surface of the male part 14 that defines the flow path 18 for liquid such as coolant includes a large-diameter cylindrical surface extending from the open end surface 14c of the male part 14 toward the female part 16, and a large-diameter cylindrical surface that extends from the cylindrical surface sequentially. It consists of a truncated conical surface extending toward the female portion 16 and a cylindrical surface with a small diameter. On the other hand, the inner circumferential surface of the female part 16 is connected to the small-diameter cylindrical surface of the male part 14 and has a truncated conical surface whose diameter gradually increases toward the open end surface 16a, and a truncated conical surface of the male part 14 that is connected to the truncated conical surface. It consists of a spherical surface 16b similar to the outer peripheral surface.

Two adjacent units 12 are connected so that the male part 14 of one unit and the female part 16 of the other unit form a spherical pair. From this, both units 12 whose axes are on a straight line
(see FIG. 1) can be pivoted relative to each other such that their axes are at an angle to each other. Needless to say, the reverse is also possible. The pivoting of both units 12 is possible until the open end surface 16a of the female part 16 abuts the cylindrical surface 14b of the male part 14 (see FIG. 2).

Further, the radius of the spherical surface 14a forming part of the outer peripheral surface of the male part 14 of each unit is larger than the radius of the spherical surface 16b forming part of the inner peripheral surface of the female part 16 of each unit. For this reason, the male part 14 and the female part 16, which form a pair of spherical surfaces, elastically deform each other in the radial direction of these spherical surfaces and come into close contact with each other on these spherical surfaces. As a result, the liquid tightness between both units 12, that is, the liquid tightness of the conduit 10, can be achieved and maintained, and the intersection angle of the axes of both units 12, that is, the connection angle can be maintained unchanged over a long period of time. can do.

As shown in FIGS. 1 and 2, a unit 12A located at one of the plurality of mutually connected units 12 has a connecting unit for attaching the conduit 10 to a machine tool (not shown), for example. 2
0 is connected to the other unit 12B, which is located at the leading edge of the other side, and a coolant is supplied to the cutting edge of the tool of the machine tool (not shown) and the workpiece fixed to the machine tool (not shown). A nozzle 22 for ejecting a liquid such as the above is connected.

The connecting unit 20 has at one end a threaded portion 24 which can be screwed into a screwing means provided on the machine tool to which the conduit 10 is attached, and has a connecting portion 26 at the other end. A hexagonal part 28 for tightening or loosening the threaded part 24 is provided between the threaded part 24 and the connecting part 26. The threaded portion 24, the hexagonal portion 28 and the connecting portion 26 have the same axis and are integrally formed of plastic material, and a flow channel (not shown) passes through their center.

The connection part 26 of the connection unit 20 is connected to the unit 1
A spherical surface 26 having the same radius as the spherical surface 14a of the male part 14 of No. 2
The connecting portion 26 and the female portion 16 of the unit 12A form a spherical pair in a state in which these spherical surfaces are elastically deformed to each other. This results in
As with the units 12, the connecting unit 20 and the unit 12A can be pivoted with respect to each other, and a liquid tightness can be provided therebetween. This pivoting causes the opening end surface 16a of the female portion 16 of the unit 12A to move toward the cylindrical surface 26 of the connecting portion.
b, and the positional relationship (connection angle) between both units 12A and 20 after pivoting can be maintained for a long time.

Referring to FIGS. 1 and 2, unit 1
The nozzle 22 connected to the unit 12B is made of plastic material and has a connecting part 30 which forms a spherical pair with the male part 14 of the unit 12B, and a tapered part 32 formed integrally with the connecting part 30. Thus, the units 12 and the nozzles 22 can be pivoted relative to each other, as well as between the units 12A and the connecting unit 20.

The connecting portion 30 has an inner circumferential surface similar to the inner circumferential surface of the female portion 16 of the unit 12. Therefore, the radius of the spherical surface forming part of the inner peripheral surface of the connecting portion 30 is smaller than the radius of the spherical surface of the male portion 14 of the unit 12B. From this, the male part 14 of the unit 12B and the nozzle 2
As with the units 12, the two spherical surfaces are in contact with each other in such a way that they press each other against the other, thereby maintaining liquid tightness between the two, and The connection angle between the two after pivoting can be maintained for a long time.

The tapered part 32 has a spout 32 that communicates with the connecting part 30.
A is provided, and a liquid such as the coolant is spouted from the spout. The tapered part 32 of the nozzle 22 has a truncated conical shape whose outer diameter gradually decreases from the boundary with the connecting part 30 toward the nozzle 32a side, instead of the example shown in FIGS. As shown in FIGS. 6 and 7, the overall shape may be such that the thickness gradually decreases and the width gradually increases toward the nozzle 32a side. In this example, the nozzle 32a can be configured not as a round hole but as a hole long in the width direction. Note that the nozzle 32a can be formed at the time of manufacturing the nozzle, but it can also be formed according to the purpose before use without being formed at the time of manufacture.

Further, the connecting portion 26 of the connecting unit 20 has the same spherical surface on the male portion 14 of the unit 12, and
The connection part 30 of the nozzle 22 is connected to the female part 1 of the unit 12.
Since each of the nozzles has the same spherical surfaces as in FIG. 6, the connection unit 20 and the nozzle 22 can be connected to form a pair of spherical surfaces, as shown in FIGS. 6 and 7. In addition, the connection unit 20
And the plastic material for forming the nozzle 22, like the unit 12, can be acetal.

In this way, the unit 12, the connection unit 20
The nozzles 22 can be connected to each other in a liquid-tight manner, and the connection angle can be changed by pivoting them.
This allows it to be curved into a desired shape. Moreover, the curved state can be maintained over a long period of time due to the connection angle. Also, by increasing or decreasing the number of connected units 12, the length of the conduit 10 can be adjusted depending on the application.
It can be easily changed depending on the purpose of use.

[Brief explanation of the drawing]

Figure 1 is a side view of the conduit according to the present invention, Figure 2 is a perspective view of the curved conduit, Figure 3 is a front view of the unit constituting the conduit, and Figure 4 is shown along line 4-4 in Figure 3. FIG. 5 is a right side view of the unit, and FIGS. 6 and 7 are a side view and a plan view showing modified examples of the nozzle. 10... Conduit, 12... Unit, 12A, 1
2B...Unit located at the cutting edge, 14, 16
... Male part and female part, 18 ... Channel, 20 ... Connection unit, 22 ... Nozzle, 24 ... Threaded part of connection unit, 26 ... Connection part of connection unit,
30... Nozzle connection part.

Claims (1)

[Scope of utility model registration request] A plurality of interconnected units each consisting of a male part and a female part, each integrally formed of an elastic material and having a flow passage passing through the center, and a nozzle formed of an elastic material and located at the leading edge. a nozzle connected to the unit, the male part of one of the two adjacent units and the female part of the other unit form a spherical pair, and the nozzle is connected to the male part of the unit located at the tip and a connecting portion forming a spherical pair with the unit, the radius of the spherical surface of the male portion of the unit being larger than the radius of the spherical surface of the female portion of the unit that is in contact with the spherical surface, and the radius of the spherical surface of the male portion of the unit being in contact with the spherical surface. the radius of the spherical surface of the connection of said nozzle tangent to the conduit.