JP2015077602A - Plunger tip of die cast machine and cooling method of plunger tip - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a plunger tip of a die cast machine and a cooling method of the plunger tip capable of improving the cooling efficiency of both of a front end surface and an outer circumferential surface.SOLUTION: A plunger tip of a die cast machine includes a front end member 11 containing a front end surface 11a which is directly brought into contact with molten metal in a plunger sleeve, an outer circumferential member 12 containing an outer circumferential surface 12a opposite to a plunger sleeve inner circumferential surface and a main body member 13 of which at least a part is included by the front end member 11 and the outer circumferential member 12, and is formed of a cooling medium channel including a first space 14 which is formed between the front end member 11 and the main body member 13 and allows a tip part 21 of a tip joint 20 to be inserted thereto, and a second space 15 which is formed between the outer circumferential member 12 and the main body member 13.

Description

  The present invention relates to a plunger tip of a die casting machine and a cooling method thereof.

  The die casting machine is an apparatus for casting a metal product having a desired shape by injecting a molten metal (molten metal) into a mold cavity in a mold and cooling and solidifying it. In general, the mold clamping direction of the mold clamping device (horizontal mold clamping / saddle mold clamping) for clamping a mold having a two-part structure with a predetermined clamping force, and injection of an injection apparatus for injecting and filling molten metal into the mold cavity There are various types of die casting machines depending on the combination of directions (horizontal injection / saddle injection).

  As an example, a horizontal die casting machine for horizontal clamping / horizontal injection and an injection apparatus thereof will be described. The horizontal die casting machine supplies molten metal (hot water supply process) by means of hot water supply or the like from the upper opening on the protruding side of a cylindrical hollow plunger sleeve that is horizontally arranged so as to protrude from the stationary platen, and the protruding end of the plunger sleeve The plunger tip inserted in the opening is advanced by the injection device, and the molten metal in the plunger sleeve is moved through the gate part in the mold that is continuous with the mold side end opening of the plunger sleeve inside the fixed platen. Injection into the mold cavity (injection process). Plural types of plunger sleeves having different inner diameters and plunger tips having different outer diameters are prepared according to the volume of the mold cavity of the mold to be used, and are replaced as necessary. Therefore, the plunger tip that is the front end of the injection device is fixed to the front end of the plunger rod via the tip joint, and the rear end of the plunger rod is concentric with the cylinder rod of the injection cylinder of the injection device by the plunger coupling. , Fixed to the front end of the cylinder rod. With such a structure, the plunger tip and the plunger rod can be integrally removed from the plunger coupling of the injection device.

  Here, a sliding gap is provided between the inner peripheral surface of the plunger sleeve and the outer peripheral surface of the plunger tip in order to advance and retract the plunger tip within the plunger sleeve in the injection process. On the other hand, the front end surface of the plunger tip is in direct contact with the molten metal supplied in the plunger sleeve from the start of the hot water supply process to the completion of the injection process, and is rapidly heated. The reaction force (metal pressure) generated in the molten metal is received. Therefore, the sliding resistance of the plunger tip fluctuates and increases due to the increase in the outer diameter of the plunger tip due to thermal expansion and the penetration (insertion) of the molten metal into the sliding gap due to metal pressure. In the worst case, the plunger tip Will seize on the plunger sleeve (chip galling).

  When such a phenomenon occurs, it becomes difficult to control the desired injection speed, and stable casting cannot be performed. In order to prevent this, a space is formed in the plunger tip, and a cooling medium such as cooling water is circulated in this space through a cooling medium flow path formed in the tip joint and the plunger rod. It is common practice to cool the plunger tip. That is, by cooling the entire plunger tip, the outer diameter of the plunger tip outer peripheral surface is prevented from increasing due to thermal expansion, and by actively cooling the front end surface of the plunger tip, the molten metal contacting the front end surface Is solidified to form a solidified layer. Through this solidified layer, the molten metal in the vicinity of the sliding gap that continues to the outer periphery of the front end surface also solidifies or prevents the molten metal from entering the sliding gap even if it does not solidify. To do.

  Patent Document 1 discloses a die casting apparatus including a sleeve (plunger sleeve) for temporarily storing molten metal and a plunger (plunger tip + plunger rod) for injecting molten metal in the sleeve into a cavity (mold cavity). A high thermal conductivity plate having a higher thermal conductivity than the material constituting the plunger tip side surface (outer peripheral surface), and the plunger is attached to the distal end surface (front end surface) of the plunger tip. Is disposed in the cylinder that forms the side surface of the plunger tip, and is provided with a diverter that allows the coolant to pass therethrough. It is formed in the central hole that blows out the coolant toward the side and the side surface of the diverter, and flows from the center of the high heat conduction plate along the back surface. A guide groove for returning the cooling water which has reached the edge of the plate to the rear, die casting apparatus which is provided is disclosed.

  Patent Document 2 discloses temperature detection means for detecting the temperatures of the injection sleeve (plunger sleeve) and the plunger tip, temperature adjustment means for adjusting the temperatures of the injection sleeve and the plunger tip, and the temperature detection means. There is disclosed a die casting apparatus including a control device for controlling the temperature adjusting means so that a clearance between an injection sleeve and a plunger tip is within a certain range based on a signal.

JP 2012-240061 A Japanese Patent Laid-Open No. 10-015652

  In the die-casting apparatus of Patent Document 1, a high thermal conductivity plate having a higher thermal conductivity than that of the material constituting the plunger tip side surface is attached to the distal end surface of the plunger tip. Then, with a diverter provided facing the back surface of the high heat conduction plate, the coolant is blown out toward the center of the back surface of the high heat conduction plate, and cooling water for cooling the back surface of the high heat conduction plate is provided on the side surface of the diverter. It is said that the high heat conduction plate can be efficiently cooled by smoothly flowing backward through the guide groove.

  In other words, the plunger tip of the die casting apparatus of Patent Document 1 only considers the improvement in cooling efficiency of the front end surface (tip surface) of the plunger tip that directly contacts the molten metal in the plunger sleeve. There is no description about the improvement of the cooling efficiency of the side surface. Therefore, even though the front end surface (high heat conduction plate) of the plunger tip can suppress the thermal expansion in the radial direction and prevent the molten metal from being inserted into the sliding gap, the plunger tip is sufficiently longer than the thickness of the high heat conduction plate. On the outer peripheral surface, the thermal expansion in the radial direction cannot be sufficiently suppressed, and there is a possibility that fluctuation and increase in sliding resistance when the plunger tip moves forward cannot be suppressed.

  On the other hand, in the die-casting apparatus of Patent Document 2, the deformation of the plunger sleeve (injection sleeve) that is horizontally disposed (in many cases, the plunger sleeve curves upward) is suppressed separately from the temperature adjusting means of the plunger tip. For this purpose, the plunger sleeve is also provided with temperature adjusting means. The plunger sleeve temperature adjusting means actually employs a structure in which a cooling jacket is provided on the outer peripheral surface of the plunger sleeve and the cooling medium flows in a cooling medium flow path formed on the outer peripheral surface of the plunger sleeve. Therefore, the structure of the plunger sleeve premised on replacement becomes special, and there is a problem in that the installation of the plunger sleeve itself is restricted or the replacement takes time.

  Further, even if the plunger sleeve can be sufficiently cooled so as not to be affected by the heat of the molten metal, as described in Patent Document 2 (paragraph 0006), there is a problem of a solidified layer generated in the molten metal and a temperature difference from the plunger tip. There is a problem.

  Above all, as in the prior art, by means of temperature adjusting means that places importance on the front end face side of the plunger tip, which merely circulates the cooling medium in the space in the plunger tip, and the temperature adjusting means of the plunger sleeve as described above In order to control the clearance between the plunger tip and the plunger sleeve so as to have a certain width, it is necessary to control and manage the flow rate and temperature of the cooling medium with high accuracy, taking into consideration the difficulty of control and the cost. And not realistic.

  The present invention has been made in view of the above-described problems, and specifically, provides a plunger tip of a die casting machine and a cooling method thereof that can improve the cooling efficiency of both the front end face and the outer peripheral face. The purpose is to do.

The above object of the present invention is at least as follows:
A front end member including a front end surface that is in direct contact with the molten metal in the plunger sleeve, an outer peripheral member including an outer peripheral surface facing the inner peripheral surface of the plunger sleeve, and a main body member that is at least partially included in the front end member and the outer peripheral member. And having
Cooling including a first space formed between the front end member and the main body member, into which a tip joint portion is inserted, and a second space formed between the outer peripheral member and the main body member. This is accomplished by the die casting machine plunger tip in which the media flow path is formed.

  That is, by making the plunger tip into a multiple divided structure as described above, the first space that becomes a part of the cooling medium flow path whose main end is the front end surface of the plunger tip and the outer peripheral surface of the plunger tip are A second space that is a part of the cooling medium flow path that is the main cooling target can be formed. At the same time, the first space can be formed by machining the end surface of the end portion on the plunger sleeve side of the body member having a cylindrical shape or the back surface of the front end member having a disk shape, and the second space has a hollow cylindrical shape. Can be formed by machining the inner surface of the outer peripheral member forming the outer periphery or the outer peripheral surface of the cylindrical main body member.

  It is basically difficult to form such a plurality of spaces in the plunger tip by boring, which is performed by inserting a tool from a drilled hole for machining the female thread for connecting the tip joint. It takes time and money, even if possible. However, since both the processing of the first space and the second space is machining of the outer surface of each member or the inner surface of the hollow portion, not only can a plurality of spaces be formed, but also the conventional boring processing. On the other hand, the degree of freedom of the processing shape of each space is dramatically improved. As a result, the cross-sectional shapes of the first space and the second space can be freely processed so as to improve the cooling efficiency of the front end surface and the outer peripheral surface of the plunger tip that cools each. Specifically, formation of grooves / concave shapes, weirs / convex shapes, etc., which become flow paths for increasing the contact area with the cooling medium or actively controlling the flow of the cooling medium Easy. Then, by forming a cooling medium flow path with these spaces as a part thereof, both the front end face and the outer peripheral face are compared with the conventional cooling method of the plunger tip in which the cooling medium freely flows into a single space having a simple shape. Cooling efficiency can be improved.

  In the plunger chip of the die casting machine according to the present invention, it is preferable that the thermal conductivity of the main body member is higher than that of the front end member and the outer peripheral member.

  The first space and the second space form a front end member that includes a front end surface that is in direct contact with the molten metal, an outer peripheral member that is in contact with the inner surface of the plunger sleeve via the lubricating layer, and the first space and the second space as described above. It is formed from a main body member including many surfaces. Therefore, if a material having a high thermal conductivity is adopted for the main body member with respect to the front end member and the outer peripheral member that require heat resistance and wear resistance using the multiple division structure of the plunger tip, the front end surface of the plunger tip and The heat receiving energy from the outer peripheral surface can be efficiently conducted to the cooling medium that flows into the first space and the second space.

  Furthermore, the plunger chip of the die casting machine according to the present invention is such that the second space has at least one of the inner peripheral surface of the outer peripheral member and the outer peripheral surface of the main body member continuous in the radial direction of the inner peripheral surface. It is preferable to form it by the recessed part of a surface. A spiral groove in which the concave portion of the second space is continuous may be used.

  The second space formed between the outer peripheral member and the main body member may be formed by a concave portion on the inner surface side of the outer peripheral member, or may be formed by a concave portion on the outer peripheral surface side of the main body member. It may be formed. If the second space is formed by a concave portion on the inner surface side of the outer peripheral member, the degree of freedom of the processing shape is slightly lower than that of the concave portion on the outer peripheral surface side of the main body member, but the inner space from the opening in the substantially fully open state This is peripheral surface processing, and the degree of freedom is sufficiently higher than boring, and a larger contact area between the outer peripheral member and the cooling medium can be secured. On the other hand, if the second space is formed by the concave portion on the outer peripheral surface side of the main body member, the degree of freedom of the processing shape is very high, and a continuous spiral groove can be processed. If the second space is formed by such a continuous spiral groove, in the longitudinal section of the plunger tip, the second space is not a continuous space but is divided at a predetermined interval, and the divided portion is Since it becomes a contact portion between the main body member and the outer peripheral member, heat conduction to the main body member having a larger heat capacity is promoted, and the flow direction of the cooling medium in the second space is controlled by the formed flow path. be able to.

  On the other hand, in the plunger tip of the die casting machine according to the present invention, at least a part of the rear end surface of the front end member is in contact with the front end surface of the front end portion of the tip joint, and the rear end surface of the front end member and the tip joint It is preferable that a plurality of grooves are formed radially in the radial direction on at least one of the front end surfaces of the front end portion.

  Generally, the distance (thickness) from the front end surface of the plunger tip to the internal space (rear end surface) is preferably as short (thin) as possible in order to increase the cooling efficiency of the front end surface. As described above, this is because the molten metal on the front end surface is solidified at the moment when the molten metal contacts the front end surface of the plunger tip, and the reaction force of the injection pressure (metal pressure) generated in the molten metal by the solidified layer formed. This is to prevent the molten metal from being inserted (entered) into the sliding gap between the plunger sleeve and the plunger tip.

  However, if the thickness of the front end portion of the plunger tip is reduced, this time, the front end portion of the plunger tip cannot be opposed to the metal pressure and is deformed in a convex shape toward the inner space. Therefore, the front end surface of the tip joint is brought into contact with and supported by the rear end surface (back surface) of the front end member, so that deformation of the front end member can be prevented even if the thickness of the front end member is reduced. Then, if a plurality of grooves are formed in a radial direction on at least one of the back surface of the front end member and the front end surface of the front end portion of the chip joint, the groove is supplied from the first supply channel at the front end portion of the chip joint. The cooling medium to be dispersed can be diffused substantially evenly on the back surface of the front end member, and can efficiently flow into the first space.

  Further, the cooling medium flow path of the plunger tip of the die casting machine according to the present invention flows the cooling medium supplied from the first supply flow path at the tip end portion of the chip joint to the first space into the second space. Then, it may be configured to be discharged from the first discharge flow path of the chip joint, or a cooling medium supplied to the first space from the first supply flow path and a first through the chip joint. The cooling medium supplied to the second space from the two supply flow paths may be discharged from the first discharge flow path.

  As in the former, the cooling medium flow path for flowing the cooling medium from the first space to the second space can form a long flow path and ensure the flow time of the cooling medium in the flow path. The heat exchange time for conducting the heat from the member and the outer peripheral member to the cooling medium becomes longer, and the cooling efficiency of the entire plunger tip can be improved. On the other hand, like the latter, the cooling medium flow path in which the supply flow paths for supplying the cooling medium to the first space and the second space are made independent (first supply flow path and second supply flow path), respectively, Cooling medium with a lower temperature that does not rise due to cooling of one space (front end member) can be directly supplied to the second space (outer peripheral member), which also improves the cooling efficiency of the entire plunger tip Can be made.

  Furthermore, the cooling medium flow path of the plunger chip of the die casting machine according to the present invention is configured such that the cooling medium flow path for the first space and the cooling medium flow path for the second space are independent of each other, and the first supply flow A cooling medium supplied from the passage to the first space is discharged from the first discharge flow path, and a cooling medium supplied from the second supply flow path to the second space is supplied to the second space via the chip joint. You may comprise so that it may discharge from a discharge flow path.

  Not only the supply flow paths for supplying the cooling medium to the first space and the second space are independent, but also the discharge flow paths for discharging the cooling medium whose temperature has increased from the respective spaces are independent (first The cooling medium flow path which is the discharge flow path and the second discharge flow path can improve the discharge efficiency of the cooling medium whose temperature has increased in each space. As a result, since the supply efficiency of the cooling medium to each space can be improved, the cooling efficiency of the entire plunger tip can be further improved.

  Here, the object of the present invention is such a plunger tip, comprising temperature detecting means for detecting a temperature in the vicinity of at least one of the front end surface of the front end member and the outer peripheral surface of the outer peripheral member, This is achieved by a method for cooling a plunger tip of a die casting machine in which at least one of a flow rate and a temperature of a cooling medium supplied to the first space and the second space is controlled. At least one of a flow rate and a temperature of the cooling medium supplied to the first space and at least one of a flow rate and a temperature of the cooling medium supplied to the second space may be controlled independently.

  That is, a temperature detection means such as a thermocouple is placed near the front end face of the front end member or the outer peripheral face of the outer peripheral member, and the flow rate and temperature of the cooling medium are controlled so that the measured temperature becomes the desired temperature. Then, since the cooling efficiency of the plunger tip of the die casting machine according to the present invention is higher than that of the conventional plunger tip, the responsiveness of the temperature control of these parts to the flow rate fluctuation and temperature fluctuation of the controlled cooling medium is high. . Therefore, the temperature controllability of an arbitrary part where the temperature measuring means is arranged can be improved as compared with the conventional plunger tip. Furthermore, in the form in which the supply flow path for supplying the cooling medium to the first space and the second space is made independent, the temperature of the front end surface of the front end member and the outer peripheral surface of the outer peripheral member can be controlled independently. The temperature control for each part of the plunger tip can be performed as necessary, the controllability of the injection speed can be improved, and the casting quality can be improved.

The plunger tip of the die casting machine according to the present invention is at least:
A front end member including a front end surface that is in direct contact with the molten metal in the plunger sleeve, an outer peripheral member including an outer peripheral surface facing the inner peripheral surface of the plunger sleeve, and a main body member that is at least partially included in the front end member and the outer peripheral member. And having
A cooling medium formed between the front end member and the main body member and into a first space into which a tip joint portion is inserted and a second space formed between the outer peripheral member and the main body member. Therefore, the cooling efficiency of both the front end face and the outer peripheral face can be improved.

  The plunger chip of the die casting machine according to the present invention further comprises a temperature detecting means for detecting a temperature in the vicinity of at least one of the front end surface of the front end member and the outer peripheral surface of the outer peripheral member, and the first space. If at least one of the flow rate and temperature of the cooling medium supplied to the second space is controlled, the high cooling efficiency allows the temperature controllability of an arbitrary part where the temperature measuring means is disposed to be changed to a conventional plunger. It can be improved with respect to the chip.

It is a schematic sectional drawing of the plunger tip of the die-casting machine concerning Example 1 of the present invention. It is a schematic sectional drawing of the plunger chip | tip of the die-casting machine which concerns on another form of Example 1 of this invention. It is a schematic sectional drawing which shows an example of other arrangement | positioning of the temperature detection means which abbreviate | omitted illustration in FIG. It is a schematic sectional drawing of the plunger chip | tip of the die-casting machine concerning Example 2 of this invention. It is a schematic sectional drawing of the plunger chip | tip of the die-casting machine which concerns on another form of Example 2 of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings.

  Embodiment 1 of the present invention will be described with reference to FIGS. First, a basic configuration of a plunger tip of a horizontal die casting machine for horizontal clamping / horizontal injection according to Embodiment 1 of the present invention will be described with reference to FIG.

  FIG. 1A is a schematic cross-sectional view in the longitudinal direction of the plunger tip 10 attached to the front end surface 30a of the plunger rod 30 via the tip joint 20. FIG. 1B is a cross-sectional view taken along arrow A in FIG. 1A, and FIG. 1C is a cross-sectional view taken along arrow B in FIG. The plunger tip 10 includes a front end member 11 that includes a front end surface 11a that directly contacts the molten metal in a plunger sleeve (not shown), an outer peripheral member 12 that includes an outer peripheral surface 12a that faces the inner peripheral surface of the plunger sleeve (not shown), and the front of the tip joint 20. A hollow portion 13 a into which the protruding portion 21 is inserted is formed, and the front end member 11 and the outer peripheral member 12 have a hollow cylindrical body member 13 that is at least partially included. The front end member 11, the outer peripheral member 12, and the main body member 13 are welded so as to be integrated after machining in a desired shape as described later, and finally the outer surface (outer peripheral surface) has desired dimensions and dimensions. Machined to precision and surface finish and heat treated as necessary.

  Between the front end member 11 and the main body member 13, the hollow portion 13a of the main body member 13 is closed and the first space 14 is formed by inserting the front protruding portion 21 of the chip joint 20 (the front of the hollow portion 13a). ). A second space 15 is formed between the outer peripheral member 12 and the main body member 13 by a continuous spiral groove processed on the outer peripheral surface of the main body member 13. The first space 14 and the second space 15 are part of a cooling medium flow path for cooling the plunger tip 10. The cooling medium flow path will be described after the other basic configuration is described.

  As shown in FIG. 1 (c), an annular groove is formed on the inner peripheral surface near the center of the hollow portion 13 a of the main body member 13 at the rear of the first space 14. The mouth is closed by the insertion of the front protrusion 21, and the discharge space 16 is formed. The discharge space 16 is also a part of the cooling medium flow path. On the other hand, on the inner peripheral surface of the rear end side of the hollow portion 13 a of the main body member 13, a female screw portion 13 b that is matched with the male screw portion 21 a that is processed at the base portion of the front protruding portion 21 of the chip joint 20 is processed. When the front protruding portion 21 of the tip joint 20 is inserted into the plunger tip 10 and screwed in until the rear end surface of the plunger tip 10 (the rear end surface 13c of the main body member 13) comes into close contact with the flange portion 22 of the tip joint 20, FIG. As shown in (b), the front end surface 21b of the front projecting portion 21 of the chip joint 20 is a portion on the back surface (cooling surface 11b) of the front end member 11 that does not have a plurality of grooves 11c radially processed in the radial direction ( It is designed to contact the contact area 11d) with an appropriate pressure.

  On the other hand, the chip joint 20 is also formed with a hollow portion 20a continuous in the longitudinal direction. The inner diameter of the inner part is different between the front part and the other part of the hollow part 20a, and the inner diameter of the front part is substantially the same as the outer diameter of the inserted water pipe 40, and is processed to the inner peripheral surface of the front part. A water pipe sealing member 40a such as an O (o) ring disposed in the groove portion seals between the inner peripheral surface of the front portion and the outer peripheral surface of the inserted water pipe 40 from the cooling medium. On the other hand, the inner diameter of the other part of the hollow portion 20a of the chip joint 20 is larger than the outer diameter of the water pipe 40, and the rear end face 20b of the chip joint 20 is interposed between the inner peripheral surface of the other part and the outer peripheral surface of the inserted water pipe 40. A continuous space is formed. A space formed between the first water supply channel 51 for supplying the cooling medium to the first space 14 and the latter inner peripheral surface of the other part of the hollow portion 20a and the outer peripheral surface of the water tube 40, the former water tube 40, Let the cooling medium be the first discharge flow path 52 that discharges the cooling medium to the outside of the plunger tip 10.

  A male threaded portion 23 a similar to the male threaded portion 21 a at the base of the front projecting portion 21 is processed in the rearward projecting portion 23 of the chip joint 20. In accordance with this, a female thread portion 30 c is processed on a part of the inner peripheral surface in front of the hollow portion 30 b formed in the longitudinal direction of the plunger rod 30. When the male screw portion 23a of the rearward protruding portion 23 of the tip joint 20 is screwed into the female screw portion 30c of the front end surface 30a of the plunger rod 30 until the front end surface 30a of the plunger rod 30 is in close contact with the flange portion 22 of the tip joint 20, The plunger tip 10, the tip joint 20, and the plunger rod 30 are integrated. And the straight base part short in a longitudinal direction is formed in the most base part of the front protrusion part 21 and the back protrusion part 23 of the chip joint 20, and a groove part is processed into the outer peripheral surface of the straight body part, and it arrange | positions in the same groove part. The cooling medium from the plunger tip 10 and the plunger rod 30 is sealed by an inlay structure formed by a sealing member 24 such as an O-ring and the inner peripheral surface of each hollow portion facing the straight body portion.

  In addition, the hollow part 30b of the plunger rod 30 does not continue over the full length. The hollow portion 30b is connected to a pipe connection port (provided on the outer peripheral surface of the plunger rod 30 at any position not shown) that does not interfere with a plunger sleeve (not shown) at the forward limit position of the plunger tip 10 in the injection process. Through the discharge outlet). Similarly, the rear end of the water pipe 40 is also penetrated and connected to a pipe connection port (supply port) provided on the outer peripheral surface of the plunger rod 30 at an arbitrary location not shown. These pipe connection ports (supply / discharge) provided on the outer peripheral surface of the plunger rod 30, a temperature adjusting device for a cooling medium (not shown), and a cooling medium supply / discharge pipe near the die casting machine installation position are connected to the outside of the machine. The plunger tip 10 is cooled by connecting the pipes in Fig. 1, but the explanation of these pipes is omitted.

  Next, the cooling medium flow path including the first space 14, the second space 15, and the discharge space 16 will be described based on the other basic configuration of the plunger tip 10 described above. A cooling medium supplied from a cooling medium supply source (not shown) to the water pipe 40 at a predetermined flow rate and a predetermined pressure via a pipe connection port (supply) (not shown) of the plunger rod 30 flows in the water pipe 40, and It collides with the cooling surface 11b of the front end member 11 of the plunger tip 10 via the front portion of the hollow portion 20a of the front protruding portion 21. The cooling medium that has collided cools the cooling surface 11b of the front end member 11 while flowing in a plurality of radially formed grooves 11c in the radial direction of the cooling surface 11b of the front end member 11 shown in FIG. . The first space 14 is filled with this cooling medium.

  Here, if a material having higher thermal conductivity than the front end member 11 and the outer peripheral member 12 is used for the main body member 13 that forms a part of the first space 14, the heat of the outer peripheral member 12 is continuous with the outer peripheral member 12. Is transmitted to the main body member 13 and further to the cooling medium filling the first space 14. Previously, the first space 14 has been described as being a part of the coolant flow path whose main cooling target is the front end surface of the plunger tip 10 (the front end surface 11a of the front end member 11). Depending on the shape and the positional relationship with the second space 15, it is possible to contribute to cooling of the outer peripheral surface of the plunger tip 10 (the outer peripheral surface 12 a of the outer peripheral member 12). Conversely, the second space 15 can also contribute to cooling the front end face of the plunger tip 10.

  A first communication channel 53 is formed between the first space 14 and the second space 15. The first communication channel 53 can be freely processed from the outer peripheral surface of the main body member 11 in the manufacturing process of the plunger tip 10, so that it corresponds to a desired supply flow rate and cooling capacity of the cooling medium or flow control of the cooling medium. Thus, it may be appropriately formed from one place to a plurality of places. The cooling medium filling the first space 14 flows as it is from the first communication flow channel 53 through the second space 15 formed as a continuous spiral flow channel, while the heat from the outer peripheral member 12 and the main body member 13 flows. Recover energy. Thus, when the 2nd space 15 is formed as a continuous flow path, the 1st communication flow path 53 is formed in the front end surface side of the plunger chip | tip 10, and a cooling medium is made to flow to the back of the outer peripheral member 12. Is preferred.

  Since the cooling medium that has flowed through the second space 15 recovers a large amount of heat energy and rises in temperature, it is preferable that the cooling medium be discharged to the outside of the plunger tip 10 as efficiently as possible. Such a cooling medium is discharged to the discharge space 16 by the second communication flow path 54 formed between the end of the flow path of the second space 15 and the discharge space 16 behind the first space 14. The Since the second communication channel 54 can also be freely processed from the outer peripheral surface of the main body member 13 in the manufacturing process of the plunger tip 10, it may be formed appropriately from one place to a plurality of places.

  The discharge space 16 forms an annular space that is continuous over the entire circumference by the insertion of the front protrusion 21 of the chip joint 20. Therefore, a groove portion is processed on the outer peripheral surface of the front protruding portion 21 so as to move back and forth in the longitudinal direction with respect to the discharge space 16, and the discharge space 16 is disposed by the discharge seal member 16 a such as an O-ring disposed in the groove portion. The cooling medium inside is sealed. Further, as shown in FIG. 1C, a third communication channel 55 penetrating the intermediate portion 20 a of the chip joint 20 is formed on the outer peripheral surface of the front protruding portion 21 that forms the inner peripheral surface of the discharge space 16. Has been. The cooling medium in the discharge space 16 passes through the third communication flow channel 55, and the first discharge flow channel 52 formed between the inner peripheral surface of the other part of the hollow portion 20 a of the chip joint 20 and the outer peripheral surface of the water pipe 40. To the outside of the plunger tip 10.

  The cooling medium flow path (discharge flow path) of the cooling medium from the second communication flow path 54 to the first discharge flow path 52 via the discharge space 16 and the third communication flow path 55 is used to control the supply amount of the cooling medium. It is preferably designed to ensure a flow rate slightly above. Further, if necessary, the second communication channel 54 and the third communication channel 55 are formed toward the center line of the chip joint 20 like the third communication channel 55 shown in FIG. First, as shown by the dotted line in the figure, it is formed so as to have a predetermined angle with the radial direction, and the cooling medium in the discharge space 16 is intentionally made to flow in a circumferential vortex, It is preferable to improve the discharge efficiency. Thus, by improving the cooling medium discharge efficiency, the inflow (supply) resistance of the cooling medium is reduced, and the supply efficiency of the cooling medium is improved. As a result, the cooling efficiency of the plunger tip 10 can be improved.

  On the other hand, the first space 14 and the second space 15 can be formed in various shapes and arrangements. As an example, FIG. 2 shows a schematic cross-sectional view of a plunger tip according to another form of the first embodiment. The same components as those in FIG. 1 are denoted by the same reference numerals. As in FIG. 1, FIG. 2 (a) is a schematic sectional view in the longitudinal direction of the plunger tip 10, and FIG. 2 (b) is FIG. 2A is a cross-sectional view taken along the arrow A, and FIG. 2C is a cross-sectional view taken along the arrow B in FIG.

  The difference from FIG. 1 is first a plurality of grooves 11c machined in the cooling surface 11b of the front end member 11 of the plunger tip 10. By increasing the amount of processing of the front end member 11 toward the front end surface 11a and deeply processing the groove 11c, a larger contact area with the cooling medium per groove is secured. At the same time, as shown in FIG. 2 (b), the cooling medium in which the groove 11 c is formed to have a predetermined angle with the radial direction and the thermal energy of the front end member 11 is recovered is intentionally formed in the first space 14. Flow in a circumferential vortex. Further, in accordance with the processing of the groove 11c, as shown in FIG. 2 (c), the same groove is processed on the front end surface 21b of the front projecting portion 21 of the chip joint 20, thereby allowing the flow of the cooling medium. It is possible to further increase the cross-sectional area of the groove 11c orthogonal to the flow rate, increase the flow rate of the cooling medium that collides with the cooling surface 11b of the front end member 11, and improve the cooling efficiency of the front end member 11.

  Next, the volume of the first space 14 is reduced, and the cooling medium filling the first space 14 is immediately flowed from the first communication channel 53 to the second space 15 formed as a continuous annular space. is there. The second space 15 is combined with the uneven shape of the inner peripheral surface of the outer peripheral member 12 formed to increase the contact area with the cooling medium rather than the flow control of the cooling medium by the continuous spiral space as shown in FIG. Thus, a shape that emphasizes an increase in the flow rate (volume) of the cooling medium is adopted, and the cooling efficiency of the outer peripheral member 12 can be improved also by such a shape. Note that the cooling medium filling the second space 15 is discharged to the discharge space 16 by the second communication flow path 54, and from the first discharge flow path 52 to the plunger tip 10 via the third communication flow path 55. Since the point of being discharged to the outside is the same, the description of the discharge channel is omitted.

  As explained so far, the plunger tip of the die casting machine according to the present invention has higher cooling efficiency of the front end surface and the outer peripheral surface than the conventional plunger tip. That is, the temperature control responsiveness of these portions with respect to the flow rate fluctuation and temperature fluctuation of the controlled cooling medium is high compared to the conventional plunger tip. Therefore, in the first embodiment or another form of the first embodiment, the vicinity of the front end surface of the plunger tip 10 (the front end surface 11a of the front end member 11) or the vicinity of the outer peripheral surface (the outer peripheral surface 12a of the outer peripheral member 12). By providing the temperature detecting means for detecting the temperature of these, the temperature controllability of these parts can be improved compared to the conventional plunger tip. The arrangement of such temperature measuring means has been omitted from FIGS. 1 and 2 in order to make the drawing easier to see. Therefore, the arrangement of such temperature measuring means in the plunger tip of the die casting machine according to the present invention will be described with reference to FIG.

  FIG. 3 is a schematic cross-sectional view showing an example of the arrangement of other temperature detecting means not shown in FIG. 1, and the same constituent members are denoted by the same reference numerals as those in FIG. 3A is a schematic sectional view in the longitudinal direction of the plunger tip 10 attached to the front end surface 30a of the plunger rod 30 via the tip joint 20, like FIG. In order to explain the arrangement of FIG. 3B is a cross-sectional view taken along arrow A in FIG. 3A, and FIG. 3C is a cross-sectional view taken along arrow B in FIG. FIG. 3D is a partial cross-sectional view showing an arrangement of temperature measuring means in a form different from that in FIG. 3A, and FIG. 3E is a cross-sectional view taken along the arrow C in FIG.

  The temperature measuring means 60 is a sheathed thermocouple. The sheath-type thermocouple is a temperature measurement sensor including a sheath (metal microtubule) enclosing a thermocouple element and an adapter (lead wire lead-out portion). Since the thermocouple wire is protected by a sheath, it has insulation and pressure resistance, and is used for temperature measurement in harsh environments such as corrosive atmospheres, places with many bends, and places with severe vibration. Therefore, it is one of the temperature measuring means suitable for measuring the temperature of the plunger tip.

  As shown in FIG. 3A, the sheath 61 of the temperature measuring means 60 is inserted to the vicinity of the front end surface of the plunger tip 10, so that the body member 13 is elongated in the longitudinal direction by reaching the inside of the front end member 11 of the plunger tip 10. A first sheath hole 60a penetrating in the direction is processed. Further, in the state in which the plunger tip 10, the tip joint 20 and the plunger rod 30 are integrated, the second sheath hole 60b and the third sheath hole 60c which are continuous with the first sheath hole 60a are formed on the tip joint 20. The flange portion 22 and the plunger rod 30 are respectively processed. Since the plunger tip 10, the tip joint 20 and the plunger rod 30 are integrated by screwing, at least in order to prevent discontinuity of these sheath holes due to a slight difference in screwing torque when the plunger tip 10 is replaced, at least, The second sheath hole 60b penetrating the flange portion 22 of the chip joint 20 has a larger outer diameter than other sheath holes, or is processed into a long hole along the circumference as shown in FIG. It is preferred that In order to make the drawing easier to see, the sheath portion 61 inserted into the first sheath hole 60a, the second sheath hole 60b, and the third sheath hole 60c is not shown.

  The rear end of the third sheath hole 60c of the plunger rod 30 is located on the outer peripheral surface of the plunger rod 30 at an arbitrary position that does not interfere with a plunger sleeve (not shown) in the forward limit position of the plunger tip 10 in the injection process. It is formed so as to be orthogonal to each other, and a screw hole for fixing the compression fitting 62 is formed on the outer peripheral surface. The compression fitting 62 is for fixing the sheath part 61 of the temperature measurement means 60 with respect to the temperature measurement object. In general, the sheath of the sheath type thermocouple is lined up with an outer diameter of 0.25 mm, and even if it is bent to a radius about three times the outer diameter, its function is not impaired. For this reason, the sheath portion 61 can be inserted to a desired position even if the hole has a right-angled portion in part.

  On the other hand, as shown in FIGS. 3 (d) and 3 (e), a threaded hole for machining a longitudinal groove on the outer peripheral surface of the plunger rod 30 and fixing the compression fitting 62 to the front end face of the groove. A form in which processing or the like is performed is also possible. Although not shown, the sheath type thermocouple also includes an attachment member with an elastic body such as a spring for pressing the sheath tip against a temperature measurement target in a state where a predetermined pressing force is applied. Therefore, it may be adopted as necessary.

  Here, FIG. 3C is a cross-sectional view for explaining the water pipe position holding spacer 41 in which the water pipe 40 is disposed at the center in the longitudinal direction of the hollow portion 30b of the plunger rod 30. One to a plurality of water pipe position holding spacers 41 may be arranged according to the length of the water pipe 40, and the cooling medium of the first discharge flow path 52 passes through the opening shown in FIG. Discharged. 1 and 2, the water pipe position holding spacer 41 is not shown because the illustration in the vicinity of the plunger tip 10 is emphasized, and the water pipe 40 is held at the front portion of the hollow portion 20a of the tip joint 20. Only explained. Therefore, although it is not directly related to the temperature measuring means 60, the water pipe position holding spacer 41 is shown in FIG. 3 (c), in which the hollow portion 30b of the plunger rod 30 is further rearward of the tip joint 20. Explain.

  In FIG. 3, the description has been made on the assumption that the temperature measuring means 60 that is a sheath type thermocouple for measuring the temperature in the vicinity of the front end face of the plunger tip 10 is used, but the first sheath hole 60 a of the main body member 13 is provided. If the front end does not reach the inside of the front end member 11 and reaches an arbitrary position near the outer peripheral surface 12a of the outer peripheral member 12, the front end of the sheath portion 61 is located near the outer peripheral surface 12a of the outer peripheral member 12. Temperature can be measured. Therefore, in the plunger tip 10, when there are a plurality of locations where temperature measurement is desired, a plurality of sheath holes having different front end positions are processed so as not to interfere with the first space 14, the second space 15, and the discharge space 16. Thus, by arranging a plurality of temperature measuring means 60, it is possible to measure the temperature at a desired plurality of locations. About such a form, since it can estimate easily from the above description and FIG. 3, detailed description is omitted.

  Next, Embodiment 2 of the present invention will be described with reference to FIGS. FIG. 4 is a schematic cross-sectional view of a plunger tip of a die casting machine according to Embodiment 2 of the present invention. FIG. 5 is a schematic cross-sectional view of a plunger tip of a die casting machine according to another embodiment of the second embodiment of the present invention. The plunger tip according to the second embodiment is different from the plunger tip according to the first embodiment in the configuration of the cooling medium flow path. The second supply flow path for supplying the cooling medium to the second space, and the cooling from the second space. And a second discharge channel for discharging the medium. Due to this difference, the first supply channel and the first discharge channel become the supply / discharge channel for the cooling medium dedicated to the first space. Since the other configuration is basically the same as that of the plunger tip of the first embodiment, the same components are denoted by the same reference numerals even if the shapes and the like are different, and only the differences from the first embodiment will be described.

  As in FIG. 1, FIG. 4A is a schematic cross-sectional view of the plunger tip 10 in the longitudinal direction. 4B is a cross-sectional view taken along arrow A in FIG. 4A, and FIG. 4C is a cross-sectional view taken along arrow B in FIG. 4A. Moreover, FIG.4 (e) is detail drawing which shows another form of the P section of Fig.4 (a). As shown in FIG. 4A, the second space 15 that is a continuous spiral space (flow path) formed between the outer peripheral member 12 and the main body member 13 is not communicated with the first space 14. Instead, a second supply channel 71 a communicating with the channel front of the second space 15 is formed so as to penetrate to the rear end surface 13 c of the main body member 13. Similarly, a second discharge flow path 72 a communicating with the rear of the flow path of the second space 15 is formed so as to penetrate to the rear end surface 13 c of the main body member 13.

  The openings of the rear end surface 13c of the main body member 13 of the second supply channel 71a and the second discharge channel 72a are arranged on a substantially concentric circle as shown in FIG. 4B. In addition, a groove is formed on the rear end surface 13c on a concentric circle so as to surround these openings, and a flange seal member 22a such as an O-ring is disposed in the groove. On the other hand, on one flange portion surface of the flange portion 22 of the chip joint 20 facing the rear end surface 13c of the main body member 13, as shown in FIG. 4C, the second supply channel 71a and the second discharge flow are formed. On the concentric circle circumference with the opening of the path 72b, a recess 22b divided into semicircular circles is processed. A second supply flow path 71b corresponding to the second supply flow path 71a and a second discharge flow path 72b corresponding to the second discharge flow path 72a pass through each of the recesses 22b to the opposing flange surfaces. Is formed.

  A similar configuration is provided between the second supply flow path 71b of the tip joint 20 and the second supply flow path 71c corresponding to the flow path and opening in the front end surface 30a of the plunger rod 30, and the tip joint. It is also formed between the 20 second discharge flow paths 72b and the second discharge flow paths 72c corresponding to the flow paths and opening on the front end face 30a of the plunger rod 30. The other flange surface of the flange portion 22 of the chip joint 20 is also processed with a concave portion 22b divided into semicircular portions, and a concentric groove is processed on the opposed front end surface 30a of the plunger rod 30. Needless to say, a flange seal member 22a such as an O-ring is disposed in the groove.

  With such a configuration, the plunger tip 10, the tip joint 20 and the plunger rod 30 are integrated via screwing, but through the recesses 22 b processed on both flange surfaces of the flange portion 22 of the tip joint 20. Thus, the continuous second supply channel 71 and second discharge channel 72 can be formed. In addition, since there is no need to directly connect the flow paths of the constituent members, slight positional deviation due to the difference in screwing amount at the time of screwing does not matter, and each flow path only needs to be continuous through the recesses. Within the semicircular recess 22b, the arrangement of the supply / discharge channels, the channel diameter, and the number of channels can be selected as appropriate.

  On the other hand, the cooling medium flowing in the water pipe 40 collides with the cooling surface 11 b of the front end member 11 of the plunger tip 10 via the front portion of the hollow portion 20 a of the front protruding portion 21 of the tip joint 20. Then, the cooling medium filling the first space 14 by this cooling medium is discharged to the discharge space 16 by the fourth communication channel 56 formed between the first space 14 and the discharge space 16. Since the fourth communication channel 56 can also be freely processed from the opening surface of the hollow portion 13a of the main body member 13 in the manufacturing process of the plunger tip 10, it may be appropriately formed from one place to a plurality of places. The cooling medium filling the discharge space 16 is the same in that it is discharged from the first discharge flow path 52 to the outside of the plunger tip 10 via the third communication flow path 55. Description is omitted.

  As described above, the cooling medium flow path in which the supply flow paths for supplying the cooling medium to the first space 14 and the second space 15 are made independent (the first supply flow path 51 and the second supply flow path 71), respectively. A cooling medium having a lower temperature, which has not increased in temperature due to cooling of the first space 14 (front end member 11), can be directly supplied to the second space 15 (outer peripheral member 12), thereby cooling the plunger tip 10 as a whole. Efficiency can be improved. Further, the discharge flow paths for discharging the cooling medium whose temperature has increased from the respective spaces are also independent of each other (the first discharge flow path 52 and the second discharge flow path 72). It is possible to improve the discharge efficiency of the cooling medium whose temperature has increased. As a result, since the supply efficiency of the cooling medium to each space can be improved, the cooling efficiency of the entire plunger tip 10 can be further improved.

  On the other hand, the discharge flow rate of the first discharge flow path 52 formed in the hollow portion 20 a of the tip joint 20 and the hollow portion 30 b of the plunger rod 30 can be sufficiently secured, and the discharge flow for discharging the cooling medium from the second space 15. There may be cases where it is not necessary to make the roads independent. In such a case, in the second embodiment of the present invention, the coolant discharge passage from the second space 15 may be joined to the first discharge passage 52 at any location in the plunger tip 10. .

  Specifically, as shown in FIG. 4D, an opening that penetrates the second discharge flow path 72a and the discharge space 16 is formed from the outer peripheral surface of the plunger tip 10 in the P portion of FIG. The opening between the second discharge flow path 72a and the discharge space 16 can be arbitrarily sealed with a first plug 72d such as a hexagon socket plug. The first plug 72d can be sealed from the outer peripheral surface of the plunger tip 10, and the opening between the second discharge channel 72a and the outer peripheral surface of the plunger tip 10 is similarly connected to the hexagon socket plug. Such a structure that can be arbitrarily sealed with the second plug 72e.

  In the above structure, if the second embodiment is performed in a state where both the first plug 72d and the second plug 72e are applied, the cooling medium is transferred to the first space 14 and the second space 15 as described above. A cooling medium flow path is formed in which the supply flow paths to be supplied are made independent of each other. On the other hand, in FIG. 4E, if the first plug 72d is not applied, the first discharge channel 52 is the only discharge channel for discharging the cooling medium from each space. At this time, although not shown, it goes without saying that a chip joint in which the second discharge flow path 72b of the flange portion 22 of the chip joint 20 is not formed (processed) is used. The opening on the rear end face 13c side of the second discharge flow path 72a of the main body member 13 is sealed by the flange seal member 22a in the recess 22 (without processing of the second discharge flow path 72b) shown in FIG. The In this case, the second discharge channel 72c of the plunger rod 30 does not need to be formed (processed).

  Furthermore, when it is desired to avoid the use of the two types of tip joints 20 depending on the presence or absence of the second discharge passages 72b, the second discharge passages 72b themselves of the tip joints 20 are not connected to the hexagon socket plugs or the like. The structure shown in FIG. 4D may be adopted between the hollow portion 30b of the plunger rod 30 and the second discharge flow path 72c.

  In the second embodiment, the second supply channel 71 and the second discharge channel 72 can be formed not only in the longitudinal hole processing but also in various shapes and arrangements. As an example, FIG. 5 shows a schematic cross-sectional view of a plunger tip of a die casting machine according to another embodiment of the second embodiment of the present invention. FIG. 5A is a schematic cross-sectional view in the longitudinal direction showing another form of the coolant supply / discharge flow path of the plunger rod 30, and FIG. 5B is an arrow A in FIG. 5A. FIG.

  The groove 73 is processed on the outer peripheral surface of the plunger rod 30 while leaving the front end portion a little. An external pipe 74 such as a copper pipe is inserted into the front end face of the groove processed portion and connected by brazing or screwing. If the opening at the other end of the opening to which the external pipe 74 is connected is aligned with the concave portion 22b of the flange surface of the flange portion 22 of the chip joint 20, a hole different from the hollow portion 30b is provided at least in the longitudinal direction of the plunger rod 30. There is no need to perform processing, and at the forward limit position of the plunger tip 10 in the injection process, if there is no interference with a plunger sleeve or the like (not shown), and if it is appropriately connected to a necessary pipe line, 2 The supply channel 71 and the second discharge channel 72 can be easily formed.

  Here, in FIG. 5, the groove portion 73 is processed on the outer peripheral surface of the plunger rod 30 while leaving the front end portion a little to completely incorporate the external pipe 74. The groove portion 73 that is continuous with the outer peripheral surface of the rod 30 is processed, and the outside of the plunger tip 10 on the rear end surface (the rear end surface 13c of the main body member 13) is directly exposed to the openings of the second supply channel 71 and the second discharge channel 72. The form which connects the piping 74 may be sufficient. In addition, a flow path connecting the external pipe 74 from the outer peripheral surface of the plunger rod 30 to the recess 22b of the flange surface of the flange portion 22 of the chip joint 20 is processed obliquely toward the axis, and the external pipe is connected to the flow path. 74 may be connected and external piping may be fixed to the outer peripheral surface of the plunger rod 30. In this case, the external pipe 74 may be processed by shallowing the groove 73 on the outer peripheral surface of the plunger rod 30 and fixed in a semi-embedded state, or if there is no interference with a plunger sleeve (not shown), the outer peripheral surface of the plunger rod 30. In addition, the external pipe 74 may be directly fixed with a metal band or the like.

  Also in the second embodiment, as described with reference to FIGS. 3 and 1 of the first embodiment, a sheath hole is constructed at a desired location, and the temperature measuring means 60 is disposed, so that the desired location can be obtained. Temperature can be measured. In particular, as in the second embodiment, in the form in which the respective portions of the front end surface of the plunger tip 10 (the front end surface 11a of the front end member 11) and the outer peripheral surface (the outer peripheral surface 12a of the outer peripheral member 12) can be cooled independently. Can arrange temperature control for each part of the plunger tip as needed by arranging a plurality of temperature measuring means 60 at each location, improving controllability of injection speed and improving casting quality be able to. Such an arrangement of the temperature measuring means 60 can be easily estimated from the above description and FIG.

  The present invention is not limited to the above embodiment and can be implemented in various ways. In the first and second embodiments, the first space and the second space are shaped symmetrically in the longitudinal direction of the plunger tip. However, in particular, as in the injection device of a horizontal die casting machine of horizontal clamping / horizontal injection, hot water supply In the process, only the lower part of the front end surface of the plunger tip is heated in contact with the molten metal, and the first space and the second space are asymmetric in the longitudinal direction of the plunger tip so as to improve the cooling efficiency of the lower part. It is good also as a shape. In the first and second embodiments, the sheath-type thermocouple is used as the temperature measuring means. However, the sheath-type thermocouple can be used as long as the temperature can be measured at an arbitrary position by arranging it near the front end surface or the outer peripheral surface of the plunger tip. It is not limited to the type thermocouple.

  Further, in the first and second embodiments, the description has been made on the assumption that the horizontal die-casting / horizontal injection horizontal die-casting machine is an injection device. However, the above-described problem is a problem to be solved even when the injection direction is soot injection. is there. In particular, in a squeeze machine or the like that employs soot injection in which the front end surface of the plunger tip is the bottom surface of the molten metal holding portion in the molten metal holding state in the plunger sleeve after completion of the hot water supply process, In addition to intrusion (insertion), it is generally necessary to prevent intrusion (insertion) into the sliding gap due to metal pressure generated by injection pressure higher than that of horizontal die casting machine injection equipment. is important. Needless to say, the plunger tip of the die casting machine and the method of cooling the plunger tip according to the present invention are also effective when employed in the plunger tip of such a spout injection device.

10 Plunger tip 11 Front end member 11a Front end surface (front end member)
11b Cooling surface (front end member)
11c Groove (front end member)
11d Contact area (front end member)
12 outer peripheral member 12a outer peripheral surface (outer peripheral member)
13 Main body member 13a Hollow part (main body member)
14 1st space 15 2nd space 16 Discharge space 20 Tip joint 21b Front end surface (chip joint)
51 1st supply flow path 52 1st discharge flow path 53 1st connection flow path 54 2nd connection flow path 55 3rd connection flow path 56 4th connection flow path 71 2nd supply flow path 72 2nd discharge flow path

Claims (10)

A plunger tip of a die casting machine, at least,
A front end member including a front end surface that is in direct contact with the molten metal in the plunger sleeve, an outer peripheral member including an outer peripheral surface facing the inner peripheral surface of the plunger sleeve, and a main body member that is at least partially included in the front end member and the outer peripheral member. And having
Cooling including a first space formed between the front end member and the main body member, into which a tip joint portion is inserted, and a second space formed between the outer peripheral member and the main body member. A plunger tip of a die casting machine in which a medium flow path is formed.   The plunger tip of the die casting machine according to claim 1, wherein the thermal conductivity of the main body member is higher than that of the front end member and the outer peripheral member.   The said 2nd space is formed in the recessed part of at least one surface of the internal peripheral surface of the said outer peripheral member, and the outer peripheral surface of the said main body member continuous in the radial direction of this internal peripheral surface. The plunger tip of the die casting machine according to any one of 2.   The plunger tip of the die casting machine according to claim 3, wherein the concave portion of the second space is a continuous spiral groove.   At least a part of the rear end surface of the front end member is in contact with the front end surface of the front end portion of the tip joint, and a plurality of surfaces are provided on at least one of the rear end surface of the front end member and the front end surface of the front end portion of the tip joint. The plunger tip of the die casting machine according to any one of claims 1 to 4, wherein the grooves are formed radially in a radial direction.   The cooling medium flow path causes the cooling medium supplied to the first space from the first supply flow path at the tip of the chip joint to flow into the second space, and then the first discharge flow of the chip joint. The plunger tip of the die casting machine according to any one of claims 1 to 5, wherein the plunger tip is configured to be discharged from a path.   The cooling medium flow path is a cooling medium supplied from the first supply flow path to the first space, and a cooling medium supplied from the second supply flow path via the chip joint to the second space. The plunger tip of the die casting machine according to any one of claims 1 to 5, wherein the plunger tip is configured to be discharged from the first discharge channel.   The cooling medium flow path discharges the cooling medium supplied from the first supply flow path to the first space from the first discharge flow path, and is supplied from the second supply flow path to the second space. The plunger chip of the die-casting machine according to any one of claims 1 to 5, wherein the cooling medium is configured to be discharged from a second discharge channel via the chip joint.   A flow rate of a cooling medium supplied to the first space and the second space, comprising temperature detecting means for detecting a temperature in the vicinity of at least one of the front end surface of the front end member and the outer peripheral surface of the outer peripheral member. The method for cooling a plunger tip of a die casting machine according to claim 6, wherein at least one of the temperature and the temperature is controlled.   Temperature detection means for detecting a temperature in the vicinity of at least one of the front end surface of the front end member and the outer peripheral surface of the outer peripheral member, and at least one of a flow rate and a temperature of the cooling medium supplied to the first space; The plunger tip of the die casting machine according to any one of claims 7 and 8, wherein at least one of a flow rate and a temperature of the cooling medium supplied to the second space is controlled independently. Cooling method.

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