JPWO2017109898A1 - Mold cooling piping - Google Patents

Abstract

Sliding telescopic tube (2) comprising a mold cooling pipe (1) comprising a first tube (2a) and a second tube (2b) slidably inserted inside the first tube (2a). In addition, the first tube (2a) and the second tube (2b) are non-circularly fitted so that they cannot be rotated relative to each other and are slidable in the axial direction. The screw can be screwed into the mold by operating the rotation operation portion (9) on the outer periphery of the rear portion of the first tube (2a).

Description

The present invention relates to a cooling pipe that is attached to a die of a die casting machine (die casting machine) or a resin injection molding machine and used for cooling the die, and more specifically, the same pipe so that the length can be changed. The present invention relates to a cooling pipe for a mold that can cope with a change in distance between mounting reference points.
Note that the following description is given by taking a cooling pipe as an example. The cooling pipe referred to here is a pipe of a type in which a tube for flowing cooling water is screwed to a mold.

  There are two types of pipes used for cooling the molds of die casting machines and resin injection molding machines: cooling pipes as shown in Non-Patent Document 1 below and plug-in cooling pipes as shown in Patent Document 1 below. is there. The present invention is intended to expand the application range by standardization (commonization), reduce costs, improve convenience, and the like for these cooling pipes.

  Conventional examples of cooling pipes are shown in FIGS. FIG. 13 shows a single path type cooling pipe, and FIG. 14 shows a reciprocating path type cooling pipe.

  The single-path type cooling pipe of FIG. 13 is formed with a taper male screw 11 for attachment at the tip of the tube 2A whose opening at the rear end is blocked, and a ring-shaped head 3 is mounted on the outer periphery of the rear part of the tube 2A. A cooling water supply / drain port (not shown) provided in the ring-shaped head is communicated with the internal passage of the tube 2A.

  In the reciprocating path type cooling pipe of FIG. 14, a taper male screw 11 for attachment is formed at the front end of the outer tube 2Ao whose rear end opening is blocked, and the inner tube 2Ai is provided inside the outer tube 2Ao. Further, the ring-shaped heads 3 and 3 are attached to the outer periphery of the rear portion of the outer tube 2Ao, and a water supply / drain port (not shown) provided in one ring-shaped head 3 is provided in the inner passage of the inner tube 2Ai. A water supply / drain port (also not shown) provided in the ring-shaped head 3 is communicated with the internal passage of the outer tube 2Ao.

  These cooling pipes are used by being connected to the mold by a method in which the taper male screw 11 is screwed into a taper screw hole formed in the mold.

  The cooling pipe is described in, for example, the following non-patent documents.

E-mail address: www.suguro.co.jp “Cooling Junction” Catalog P27-29 JP 2009-101390 A

  The length of the conventional cooling pipe described above is fixed. For this reason, there are problems that many pipes having different lengths according to individual mold designs are required, and that mass production cannot be expected since the molds can be manufactured only after the mold design is completed.

  In this way, the cooling piping made according to the mold design is naturally expensive. The use of many high-priced cooling pipes increases the cost of molding and is undesirable for the user.

  Further, the screw hole for connecting the cooling pipe formed in the mold is inevitably corroded over time, and the screw hole is recut to cope with the corrosion of the screw hole. In that case, the length between the attachment reference points naturally changes.

  At that time, it is necessary to replace all the cooling pipes at the locations where the screw holes have been recut according to the changed length between the reference planes, which is also a major factor in increasing the cost burden.

  The plug-in type cooling pipe described in the above-mentioned Patent Document 1 can cope with a slight variation in the length between the reference planes by changing the amount of insertion into the connection hole of the mold. However, since this pipe also has a limit in the amount of cooling pipe inserted into the connection hole of the mold, it cannot cope with the fluctuation in the length between the reference planes exceeding the limit.

  Therefore, an object of the present invention is to make the cooling pipes for molds common (integration of types) so as to be able to cope with the variation in the distance between the mounting reference points with the same cooling pipe.

In order to solve the above-mentioned problems, in the present invention, for a die having a tapered male screw on the outer periphery of the distal end of a tube through which cooling water passes, the male screw is screwed into a screw hole of the die and connected to the die. The cooling pipe was configured as follows.
That is, the tube has a water supply / drain port and a rotation operation portion on the outer periphery of the rear portion, and further, a first tube having an end plug attached to the opening portion of the rear end, and the rear portion side is first from the front end opening of the first tube. It is configured as a slide telescopic tube that is slidably inserted inside the tube, and is composed of a second tube having a male screw with a taper on the outer periphery of the tip.
Between the inner periphery of the first tube and the outer periphery of the second tube, a seal material between the tube gaps compressed in the axial direction is disposed,
The water supply / drain port communicates with the internal passages of the first tube and the second tube,
The rear end side of the first tube and the rear end portion of the second tube are non-circularly fitted so that they cannot rotate relative to each other and are slidable in the axial direction.

  In addition, with respect to the plug-in type cooling pipe, a seal ring that seals a space between the connection hole of the mold is attached to the outer periphery of the tip of the second tube in place of the male screw.

  In addition to the mold cooling pipe described above, the present invention includes a third tube disposed on the inner side of the second tube with the tip protruding from the second tube with respect to the cooling pipe, and the interior of the third tube. A water supply / drain port that further connects the passage to the outside is additionally provided, and the internal passage between the third tube, the first tube, and the second tube is provided as an outward passage of the third tube, and an internal passage between the third tube, the first tube, and the second tube. A cooling pipe for a mold that is used as a return path for cooling water or a plug-in type is also provided.

  The cooling pipe without the third tube is used as a single-path cooling pipe, and the cooling pipe with the third tube is a cooling water inlet for the water supply / drain port on the side communicating with the internal passage of the third tube. The water supply / drainage port on the side communicating with the internal passages of the first and second tubes is used as a cooling water drainage port and used as a reciprocating path type cooling pipe.

  The water supply / drain port is provided with a ring-shaped head attached to the outer periphery of the rear portion of the first tube, and a seal ring for generating an annular space defined on the inner periphery near both ends of the ring-shaped head on the outer periphery of the first tube. In addition, it is preferable that a hose joint leading to the annular space is provided outside the ring-shaped head and the hose joint is used.

  It is preferable that the ring-shaped head is rotatable rather than the one fixed to the first tube because the positions of the water supply / drainage port and the second water flow port can be freely changed. One water supply / drain port is communicated with the internal passage of the first tube through a hole formed in the end plug.

  Further, another water supply / drain port provided in the reciprocating path type cooling pipe is communicated with the internal passage of the third tube through a hole formed in the end plug.

  All of the first to third tubes are preferably formed of stainless steel having excellent corrosion resistance.

  The sealing material may be formed of an organic material such as rubber for a cooling pipe for a die casting machine or a resin molding machine in which the mold temperature rises to about 300 ° C.

  On the other hand, for cooling pipes for gravity casting machines and low pressure casting machines where the mold temperature rises to near 400 ° C, it is difficult to maintain durability with organic sealing materials, so it is better to use metal sealing materials. .

  In addition, both the rear side inner periphery of the first tube and the rear side outer periphery of the second tube are circular in cross section, and the sealing material is disposed between the second tube outer periphery and the first tube inner periphery of the circular cross section. It is good to arrange.

  The axial compression of the sealing material is performed by a method adopted in a seal portion of a general pipe joint, that is, a sealing material receiving metal fitting is arranged inside the first tube, and further, the inner periphery of the tip of the first tube A screw hole is formed in the screw hole, a tightening ring is screwed into the screw hole, and a sealing material is sandwiched between the tightening ring and the seal material receiving metal fitting.

  In the cooling pipe for a mold according to the present invention, the second tube is slidable in the axial direction with respect to the first tube, and the entire length is freely changed by changing the insertion amount of the second tube with respect to the first tube. be able to.

  Thereby, it becomes possible to cope with the variation in the distance between the mounting reference points with the same cooling pipe, so that the cooling pipes for molds can be shared and the types can be integrated.

  Further, with respect to the mold cooling pipe, the tube may be inserted into a hole provided in the mold holder, and the tapered male screw on the outer periphery of the tip of the tube may be screwed into the screw hole of the mold. In use, it is not possible to provide a rotation operation unit for engaging a rotation operation tool such as a spanner with the first tube.

  Therefore, in the present invention, with respect to the mold cooling pipe, the rear end side of the first tube and the rear end portion of the second tube are non-circularly fitted so as not to be relatively rotatable. Due to the non-circular fitting structure, the rotation of the first tube is transmitted to the second tube, and the rotation operation portion formed on the first tube is operated to enable screw connection of the tip of the second tube to the mold. It was.

It is a side view which shows an example (single path | route type cooling piping) of the cooling pipe for metal mold | dies of this invention. It is sectional drawing of the cooling pipe for metal mold | dies of FIG. It is a decomposition | disassembly side view of the cooling pipe for metal mold | dies of FIG. It is sectional drawing along the IV-IV line of FIG. It is a side view which shows the other form of a 2nd tube. It is an expanded sectional view of the seal part of the 1st tube and the 2nd tube. It is a side view which shows the other example (reciprocating path type cooling piping) of the cooling pipe for metal mold | dies of this invention. It is sectional drawing of the cooling piping for metal mold | dies of FIG. It is a top view which shows an example of the metal mold | die of the die-casting machine which employ | adopted the cooling pipe for metal mold | dies of this invention. It is a perspective view of the metal mold | die of FIG. It is sectional drawing which shows the other example of the single path | route type cooling piping of this invention. It is sectional drawing which shows the other example of the reciprocating path type | mold cooling piping of this invention. It is a side view which shows an example of the conventional single path | route type cooling piping. It is a side view which shows an example of the conventional reciprocating path type | mold cooling piping.

  Hereinafter, an embodiment of a cooling pipe for a mold according to the present invention will be described with reference to FIGS. 1 to 10 is a screw type.

  FIGS. 1-6 has shown the specific example of the cooling piping 1 for single path | route type molds. This single-path mold cooling pipe 1 includes a slide telescopic tube 2 composed of two members, a first tube 2a and a second tube 2b whose outer diameter is smaller than the inner diameter of the first tube, and the first tube. 2a has a ring-shaped head 3 mounted on the outer periphery of the rear part.

  Further, a sealing material 4 (see FIGS. 2, 3, and 6) between the tube gaps disposed between the inner periphery of the first tube 2a and the outer periphery of the second tube 2b, and the sealing material 4 in the axial direction. And a fastening ring 6 (also see FIGS. 2, 3, and 6), and a washer 7 interposed between the fastening ring 6 and the sealing material 4.

The first tube 2a is provided with a water supply and drainage port 8 _-1 and the rotation operation portion 9 through which cooling water to the rear outer periphery (refer to FIG. 1, FIG. 3). The water supply / drain port _8-1 serves as an inlet for the cooling water. The illustrated water supply / drain port _8-1 is constituted by a hose joint provided on the ring-shaped head 3.

  Further, the first tube 2a has an end plug 10 (see FIGS. 2, 3, and 6) attached to the rear end opening.

  The rear side of the second tube 2b is slidably inserted from the front end opening of the first tube 2a into the first tube 2a. The second tube 2b has a tapered male screw 11 for attachment on the outer periphery of the tip, and the male screw 11 is screwed in a liquid-tight manner into a screw hole formed in a mold.

As shown in FIG. 2, the ring-shaped head 3 has a seal groove 3 a on the inner periphery near both ends, and the ring seal 3 b incorporated in each seal groove 3 a includes the first tube 2 a and the ring-shaped head 3. fractionating an annular space S from the outside, the first water passage 8 _-1 through a hole formed in the annular space S and the end plug 10 is communicated with the internal passage of the first tube 2a between.

The illustrated ring-shaped head 3 is provided with a rotatable one. This outer periphery of the ring-shaped head 3 is hose fitting is secured, the hose fitting constitutes the plumbing port _28-1 provided in the first tube 2a.

  The sealing material 4 is mounted on the outer periphery of the second tube 2b, and is interposed between the sealing material receiving metal fitting 5 and the fastening ring 6 that are inserted into the first tube 2a.

  As shown in FIG. 6, the seal material bracket 5 is held in place by engaging with a step portion formed inside the first tube 2 a.

  The tightening ring 6 is screwed into a screw hole formed in the rear portion of the second tube 2b, and the sealing material 4 is compressed in the axial direction by the screwing, and the sealing material 4 is the inner peripheral surface of the first tube 2a. Are pressed against the outer peripheral surface of the second tube 2b, and the space between the first tube 2a and the second tube 2b is liquid-tightly sealed. The sealing material 4 may be an O-ring.

  The washer 7 is provided for the purpose of preventing a strong twisting force from being applied to the sealing material 4 by causing a slip between the fastening ring 6 when the fastening ring 6 is tightened. This washer 7 may be omitted when the sealing material 4 is a metal.

  The rotation operation unit 9 is created by processing the outer periphery of the rear portion of the first tube 2a into a hexagon, and an operation tool (spanner) is applied to the rotation operation unit 9 to apply a rotational force to the first tube 2a.

  The male screw 11 can be formed integrally with the second tube 2b by cutting a thick pipe made of the material of the second tube 2b. However, a separately processed hollow screw ring is formed after the second tube 2b. What was created by joining (brading) the outer periphery of the end with brazing material is preferable because the cutting process of the pipe is omitted.

  The inner periphery of the rear side of the first tube 2a and the outer periphery of the rear end of the second tube 2b are non-circularly fitted so as to be slidable in the axial direction and not to be relatively rotatable.

  In the non-circular fitting, the first tube 2a is provided with a non-circular hole (a hexagonal hole in the drawing) 12a shown in FIGS. 2, 4, and 6 and further on the outer periphery of the rear portion of the second tube 2b. A non-circular portion 12b having a non-circular cross-section is provided in correspondence with the non-circular hole 12a, and the non-circular hole 12a and the non-circular portion 12b having a non-circular cross-section are axially slidable. It is realized by fitting to.

  The non-circular portion 12b provided in the second tube 2b is created by a ring having a non-circular outer diameter surface joined to the outer periphery of the second tube 2b with a brazing material, as shown in FIGS. As shown in FIG. 5, it may be either a forging surface integrally formed at the end of the second tube 2b. The latter method is advantageous from the viewpoint of production cost.

  The first tube 2a and the second tube 2b are prevented from rotating relative to each other by the non-circular fitting of the non-circular hole 12a and the non-circular portion 12b, and the rotation operation portion 9 is operated to add to the first tube 2a. The rotating force thus transmitted is transmitted to the second tube 2b via the non-circular fitting portion.

  The exemplary mold cooling pipe 1 configured as described above can change the length of the cooling pipe within a range in which the sliding of the second tube 2b is allowed. It is possible to cope with fluctuations in distance.

  Further, the male screw 11 at the tip of the second tube 2b can be screwed into the screw hole of the mold by operating the rotary operation unit provided on the first tube 2a, and the rotation operation unit can be installed on the second tube 2b. Even when it is not allowed, it is not subject to use restrictions, and it is possible to make the mold cooling pipes common and to integrate the types.

7 and 8 are specific examples of a reciprocating path type mold cooling pipe 1A. This reciprocating path type mold cooling pipe 1A has a third tube 2c disposed on the inner side of the second tube 2b with the tip protruding from the second tube 2b with respect to the cooling pipe 1 of FIGS. In addition, a water supply / drain port _8-2 is further provided for communicating the internal passage of the third tube 2 c to the outside.

  The third tube 2c is a tube having a fixed length. The third tube 2c preferably has a length in consideration of the maximum assumed depth of the cooling water introduction hole formed in the mold.

  Such a third tube has an extra length portion on the tip side depending on the depth of the cooling water introduction hole formed in the mold. By cutting off the extra length, it can be adjusted to an appropriate length and used.

The rear portion of the third tube 2c is closed by the end plug 10 in the same manner as the second tube 2b. Moreover, water supply and drainage port 8 _-2, and further one additionally provided a ring-shaped head 3 to be mounted on the rear outer circumference of the first tube 2a, similarly to the plumbing port _28-1, a tube joint which is provided on the outer periphery of the ring-shaped head It is composed.

  The end plug 10 employed in the reciprocating path mold cooling pipe 1A has a hole for communicating the inner annular space s of one ring-shaped head 3 with the internal passage of the third tube 2c, and the other ring-shaped. There is a hole for communicating the annular space s inside the head 3 with the internal passage of the first tube 2a.

Thus configured reciprocating path type of the mold cooling pipe 1A is forward of the cooling water internal passage of the third tube 2c that communicates plumbing port _8-2 and its plumbing port _8-2 is supplied from the outside , the internal passage of the internal passage and the second tube 2b of the first tube 2a in communication with the other water supply and drainage port 8 _-1 and its plumbing port _28-1 is used respectively as a return of the coolant.

  Other configurations are the same as those of the single-path mold cooling pipe 1 described above, and thus the description thereof is omitted. This reciprocating path type mold cooling pipe 1 </ b> A also responds to fluctuations in the distance between the reference points attached by the same cooling pipe by expanding and contracting the slide telescopic tube composed of the first tube 2 a and the second tube 2 b. be able to.

  Similarly to the single-path mold cooling pipe 1, the rotation operation unit 9 provided on the outer periphery of the rear portion of the first tube 2 a is operated to make the male screw 11 at the tip of the second tube 2 b into the screw hole of the mold. Can be screwed together.

  An example of the use of the mold cooling pipe of the present invention is shown in FIGS. The mold 21 having the illustrated design has four through water cooling holes and four through water cooling holes. H1 to H4 are through water cooling holes, and H5 to H8 are non-through water cooling holes.

  The through water cooling holes H1 and H2 and the non-through water cooling holes H5 and H6 (see FIG. 10) are processed in the fixed mold 21a, and the through water cooling holes H3 and H4 are processed in the movable mold 21b. In addition, the non-penetrating water cooling holes H7 and H8 are partly processed into the fixed mold 21a, and the remaining part is processed into the movable mold 21b.

  A pair of single-path type mold cooling pipes 1 are connected to both ends of the through-water cooling holes H1 to H4, respectively, and the cooling water passes through one of the pair of single-path type mold cooling pipes 1 through water cooling. The cooling water is discharged from the other single-path mold cooling pipe.

In addition, the non-through water cooling hole H5～H8, round-trip path-type mold cooling pipe 1A are respectively connected, a water supply and drainage port _8-2 of the round-trip path-type mold cooling pipe 1A third tube cooling water introduced respectively via 2c to the non-penetrating water-cooling holes H5~H8 is a tube 2a1, is discharged from the water supply and drainage port 8 _-1 through the interior passage of the second tube 2b.

  The four reciprocating die cooling pipes 1A are connected to the fixed die 21a, and the non-through water cooling holes H7 and H8 are when the movable die 21b is abutted against the fixed die 21a. In addition, the portion processed into the fixed mold 21a and the portion processed into the movable mold 21b are connected to each other.

  Further, in the abutting state of the fixed mold and the movable mold, the distal end side of the third tube of the reciprocating path mold cooling pipe 1A enters the non-through water cooling holes H7 and H8 processed into the movable mold 21b. Yes.

  The single-path mold cooling pipe 1 employed in the illustrated mold 21 is attached to one connected to both ends of the through water cooling holes H1, H2 and one connected to both ends of the through water cooling holes H3, H4. The reference length is different.

For example, the die-casting machine shown in FIG. 9 has different lengths L1, L2, and L3 from the four side surfaces of the mold holder 20 to the mold 21 serving as the reference for mounting the cooling pipe, and only the portions that appear in the drawing. , Cooling pipes that match each length are required.
Note that a member for regulating the installation position of the rear portion of the cooling pipe may be disposed near the mold holder 20, but FIG. 9 is a diagram in which that member is omitted.

  As shown in FIG. 10, a cooling pipe that is perpendicular to the single-path mold cooling pipe 1 shown in FIG. Therefore, when using conventional cooling pipes with fixed lengths, five types of cooling pipes are required for the molds of FIGS.

  On the other hand, the single-path mold cooling pipe 1 and the reciprocating-path mold cooling pipe 1A of the present invention absorb the difference in the reference length of attachment by changing the length of the slide telescopic tube 2. can do. Therefore, the cooling pipe connected to both ends of the through water cooling holes H1, H2 and the cooling pipe connected to both ends of the through water cooling holes H3, H4 may be the same product.

  The cooling pipe connected to the non-through water cooling holes H5 and H6 and the cooling pipe connected to the non-through water cooling holes H7 and H8 may be the same product.

  Therefore, the exemplary mold can be cooled using two types of cooling pipes. Further, the cooling pipe can be manufactured before the mold design is completed, and the types of cooling pipes can be integrated and mass-produced.

  Thereby, shortening of the manufacturing time of a die-casting machine and a resin injection molding machine, reduction of manufacturing cost, etc. can be aimed at.

  11 and 12 show an embodiment of a plug-in mold cooling pipe. FIG. 11 shows a single-path mold cooling pipe, and FIG. 12 shows a reciprocating-path mold cooling pipe.

  In these mold cooling pipes 1B and 1C, a seal ring 13 is mounted on the outer periphery of the second tube 2b in place of the male screw provided in the second tube 2b in the mold cooling pipe of FIGS. doing. Moreover, the collar 14 is provided in the outer periphery of the 2nd tube 2b.

  The seal ring 13 is located between the mold connection hole (not shown) and when the second tube 2b is inserted to a position where the flange 14 abuts against the inlet of the connection hole. The space between the second tube 2b is interposed in a liquid-tight manner.

  Other configurations are the same as those of the mold cooling pipes shown in FIGS.

  The length of the insertion mold cooling pipe can be adjusted within a range in which the second tube 2b is allowed to slide, and the types of cooling pipes can be integrated and mass-produced.

  1 to 3, 7, 8, 11, and 12, 15 is a retaining ring made of a wire spring. The retaining ring 15 is rotatably supported by the last ring-shaped head 3. After the end plug 10 is assembled, the retaining ring 15 is fitted into an annular groove provided on the outer periphery of the rear end of the end plug 10, thereby preventing the end plug 10 from coming off.

  The illustrated retaining ring 15 can be engaged with and detached from the annular groove of the end plug by so-called one-touch. However, the end plug can be retained using a known snap ring or the like.

1, 1A Mold cooling pipe 2 Slide telescopic tube 2a First tube 2b Second tube 2c Third tube 2A Tube 2Ao Outer tube 2Ai Inner tube Ip _1, Ip ₂ Internal passage 3 Ring-shaped head s Annular space 3a Seal groove 3b ring seal 4 sealing member 5 with the sealing member receiving metal 6 clamping ring 7 washer _{8 -1, 8-2} plumbing port 9 rotation operating part 10 the end plug 11 external thread 12a non-circular cross section of the hole 12b noncircular portion 13 sealing ring 14 flange 15 Retaining ring 20 Mold holder 21 Mold 21a Fixed mold 21b Movable molds L1 to L3 Mounting reference lengths of cooling pipes H1 to H4 Through water cooling holes H5 to h8 Non-through water cooling holes

Claims (8)

A die cooling pipe (1) comprising a tapered male screw (11) on the outer periphery of the distal end of a tube through which cooling water passes, the male screw being screwed into a screw hole of the die and connected to the die,
The tube is provided with a water supply / drain port (8 ₋₁ ) and a rotation operation part (9) on the outer periphery of the rear part, and further, a first tube (2a) in which an end plug (10) is attached to an opening part of the rear end; From the second tube (2b) having the tapered outer thread (11) on the outer periphery of the distal end, the rear side of the first tube (2a) being slidably inserted into the first tube (2a) from the distal end opening of the first tube (2a) Is configured as a slide telescopic tube (2)
Between the inner periphery of the first tube (2a) and the outer periphery of the second tube (2b), a seal material (4) between the tube gaps compressed in the axial direction is disposed,
The water supply / drain port (8 _-1 ) communicates with the internal passage (Ip ₁ ) of the first tube (2a) and the second tube (2b),
A cooling pipe for a mold in which a rear end side of the first tube (2a) and a rear end portion of the second tube (2b) are non-rotatably fitted and non-circularly fitted so as to be axially slidable.   2. The mold according to claim 1, wherein a seal ring (13) for sealing a space between the outer periphery of the second tube (2 b) and a connection hole formed in the mold is mounted instead of the male screw (11). Cooling piping. The mold cooling pipe according to claim 1 or 2, wherein a third tube (2c) is disposed inside the second tube with a tip projecting from the second tube (2b), and the third tube ( internal passage (Ip ₂₎ of the water supply and drainage port to communicate with the external 2c) _{(8 -2)} further comprising a inner passage (Ip ₂₎ is forward of the cooling water supplied from the outside of the third tube (2c), Mold cooling pipes in which the internal passages (Ip ₁ ) of the first tube (2a) and the second tube (2b) are respectively used as a return path for cooling water. The first tube (2a) is provided with a sealing material receiving metal fitting (5) disposed inside, and a tightening ring (6) screwed into the inner periphery of the tip. The tightening ring (6) and the sealing material receiving material are provided. The mold cooling pipe according to any one of claims 1 to 3, wherein the sealing material (4) is sandwiched between the metal fitting (5) and the sealing material (4) is compressed in the axial direction.   A non-circular hole (12a) provided in the rear end side of the first tube (2a) and the rear end portion of the second tube (2b) is provided on the rear side of the first tube (2a). The outer diameter surface provided on the outer periphery of the rear portion of the second tube (2b) corresponding to the non-circular hole (12a) is axially slidable in the non-circular portion (12b). The mold cooling pipe according to any one of claims 1 to 4, wherein the mold cooling pipe is inserted.   The noncircular portion (12b) on the outer periphery of the rear portion of the second tube (2b) is created by a ring having an outer diameter surface having a noncircular cross section joined to the outer periphery of the second tube (2b). The mold cooling pipe according to any one of 5.   The noncircular portion (12b) on the outer periphery of the rear portion of the second tube (2b) is a forged molding surface, and is integrally formed with an end portion of the second tube (2b). The cooling pipe for the mold described.   The mold cooling pipe according to any one of claims 1 to 7, wherein the male screw (11) is constituted by a hollow screw ring joined to a tip outer periphery of the second tube (2b).

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