CN110280669B

CN110280669B - Supporting cooling tank structure of cooling based on stamping die

Info

Publication number: CN110280669B
Application number: CN201910716600.0A
Authority: CN
Inventors: 陈冲
Original assignee: Zhuzhou Ed Stamping Products Manufacturing Co ltd
Current assignee: Zhuzhou ed stamping products manufacturing Co.,Ltd.
Priority date: 2019-08-08
Filing date: 2019-08-08
Publication date: 2021-05-07
Anticipated expiration: 2039-08-08
Also published as: CN110280669A

Abstract

A matched cooling tank structure based on a stamping die comprises an upper die fixing plate, a lower die fixing plate and a stamping lower die; the inner side of the upper die fixing plate is fixedly provided with an upper stamping die through bolts, and the upper stamping die consists of an upper die core, an upper die cooling plate and a die core supporting heat dissipation plate; a stamping lower die is fixedly mounted on the inner side of the lower die fixing plate through bolts; the upper die core and the lower die core are designed correspondingly; the upper die fixing plate is correspondingly installed on the upper side of the lower die fixing plate, and the upper die fixing plate and the lower die fixing plate are connected through the guide posts in a sliding mode. This cooling lower bolster that supporting cooling bath structure based on stamping die was equipped with's inside has been seted up the cooling water chamber, and the left and right sides of cooling lower bolster all communicates and is provided with the cooling water and inserts the pipe, and the cooling water inserts the pipe and is connected with external cooling device, is favorable to inserting the pipe through the cooling water and pours into the cooling water into the cooling lower bolster inner chamber fast in the middle of to the realization is to the rapid cooling operation of punching press lower mould.

Description

Supporting cooling tank structure of cooling based on stamping die

Technical Field

The invention relates to the technical field of die equipment, in particular to a matched cooling tank structure based on a stamping die.

Background

The stamping die is a special process equipment for processing materials (metal or nonmetal) into parts (or semi-finished products) in cold stamping, and is called cold stamping die (commonly called cold stamping die). Stamping, which is a press working method for obtaining a required part by applying pressure to a material at room temperature by using a die mounted on a press machine to cause separation or plastic deformation; the stamping die can generate a large amount of heat in the using process, if the heat cannot be quickly generated, the stamping die and a stamping part can be damaged, and therefore a cooling device needs to be additionally arranged on the stamping die.

The invention, which is found in the prior patent No. 201810449518.1 through patent retrieval, discloses a cast iron stamping die with shock absorption and rapid cooling functions, which comprises a shell, a die groove, a fixing frame and a function pipe, wherein a first reset spring, a second reset spring and a vertical sliding groove are arranged on the inner side of the shell, the bottom end of the outer side of the die groove is connected with a spring telescopic rod, a lower die and a push rod hole are arranged at the top of a lower die box, the fixing frame is installed on the bottom surface of the lower die, a hard pipe is connected with a hose, the function pipe is connected with the hose, and the function pipe is arranged inside a function block. This cast iron stamping die with shock attenuation and quick cooling function has adopted the damping device of symmetric distribution, has reduced and has produced vibrations and noise in the stamping process, has avoided the too big influence that causes the punching press product of vibrations to set up the quick cooling device to stamping die, avoided because the overheated product that leads to of mould warp or the unqualified condition of product appears.

The invention with patent number 201810426592.1 discloses a rapid cooling shockproof stamping die, which comprises two brackets, wherein the two brackets are distributed on the left, the right side both sides, support middle part fixedly connected with dog, fixed surface installs first spring on the dog, support middle part passes inside in the middle of the first spring, support top surface contact is connected with first slider, the quantity of first slider is two, connecting rod on the inboard fixedly connected with of two first sliders, go up the mould on the middle inside fixedly connected with of connecting rod, it has the punching press head to go up mould lower surface middle part fixed mounting, go up mould lower surface left and right sides fixedly connected with locating pin, locating pin fixed surface installs the rubber pad, two inboard fixedly connected with lower connecting rod in support below, inside fixedly connected with bed die in the middle of the lower connecting rod, bed die top middle part is equipped with the punching press groove. The stamping die has good cooling and shockproof effects, good material forming effect, prolonged service life and strong practicability.

The existing matched cooling tank based on the stamping die is simple in structural design, most of the cooling water is supplied to the round grooves in the upper part and is cooled, the cooling mode is single, the cooling effect is poor, and the cooling speed is slow.

Therefore, the structure aims at the existing structure and defects to be researched and improved, and a matched cooling tank structure based on a stamping die is provided.

Disclosure of Invention

The invention aims to provide a matched cooling tank structure based on a stamping die, and aims to solve the problems that the structural design provided in the background art is simple, a plurality of circular grooves are formed for cooling water to cool, the cooling mode is single, the cooling effect is poor, and the cooling speed is slow.

The purpose and the effect of the matched cooling tank structure based on the stamping die are achieved by the following specific technical means:

a matched cooling tank structure based on a stamping die comprises an upper die fixing plate, a lower die fixing plate, a stamping lower die, a cooling lower die plate, a cooling water circulating pipe, a lower die cooling fin, a lower die core, a supporting cooling column, a circulating cooling water cavity, a stamping upper die, an upper die core, an upper die cooling plate, a die core supporting cooling plate and a cooling water access pipe; the inner side of the upper die fixing plate is fixedly provided with an upper stamping die through bolts, and the upper stamping die consists of an upper die core, an upper die cooling plate and a die core supporting heat dissipation plate; the stamping lower die is fixedly installed on the inner side of the lower die fixing plate through bolts and consists of a cooling lower die plate, a cooling water circulating pipe, lower die cooling fins, a lower die core, a supporting cooling column and a circulating cooling water cavity; the upper die core and the lower die core are designed correspondingly; the upper die fixing plate is correspondingly installed on the upper side of the lower die fixing plate, and the upper die fixing plate and the lower die fixing plate are connected through the guide posts in a sliding mode.

Furthermore, a cooling water cavity is formed in the cooling lower template, the left side and the right side of the cooling lower template are communicated with cooling water inlet pipes, and the cooling water inlet pipes are connected with an external cooling device.

Furthermore, the lower die core is arranged on the top end face of the cooling lower die plate, a plurality of supporting heat dissipation columns are arranged on the bottom side array of the lower die core, the lower die core is supported on the bottom end face of the inner cavity of the cooling lower die plate through the supporting heat dissipation columns, and the supporting heat dissipation columns are made of copper materials.

Furthermore, both sides of the lower die core are symmetrically provided with lower die cooling fins, the lower die cooling fins are covered on the side walls of the two ends of the lower die core in an array manner, and the lower die cooling fins are also connected in the inner cavity of the lower cooling template in a sealing manner.

Furthermore, the side walls of the two ends of the lower die core are respectively provided with a circulating cooling water cavity, and the circulating cooling water cavities are communicated with the inner cavity of the lower cooling template through cooling water circulating pipes.

Furthermore, a cooling water cavity is also formed in the upper die cooling plate, cooling water access pipes are symmetrically arranged on two sides of the upper die cooling plate, and the upper die cooling plate is communicated with an external cooling device through the cooling water access pipes.

Further, go up the mould core and fix and set up on the downside terminal surface of last mould cooling plate, and go up the top side terminal surface of mould core and go up the array and be provided with the mould core and support the heating panel to go up the mould core and support on the inner chamber top surface of last mould cooling plate through mould core support heating panel.

Furthermore, rectangular notches are symmetrically formed in the end faces of the inner sides of the two ends of the upper die fixing plate and the lower die fixing plate, and the cooling water inlet pipe is connected with an external cooling device through the notches.

Compared with the prior structure, the invention has the following beneficial effects:

the cooling water chamber has been seted up to the inside of the cooling lower bolster that is equipped with, and the left and right sides of cooling lower bolster all communicates and is provided with the cooling water and inserts the pipe, and the cooling water inserts the pipe and is connected with external cooling device, is favorable to inserting the pipe through the cooling water and pours into the cooling water into the cooling lower bolster inner chamber into fast in the middle of to the realization is to the rapid cooling operation of punching press lower mould.

The lower mould mold core that is equipped with sets up on the terminal surface of the top of cooling lower bolster, and the bottom side array of lower mould mold core is provided with the many places and supports the heat dissipation post, and the lower mould mold core supports on the inner chamber bottom terminal surface of cooling lower bolster through supporting the heat dissipation post, and support the heat dissipation post and make for copper material, the design of supporting the heat dissipation post is first to be favorable to carrying out effectual support to the lower mould mold core, secondly can increase the radiating effect of lower mould mold core, and the design that supports the heat dissipation post for the copper post makes the heat dissipation of this lower mould mold core more rapidly and even.

The equal symmetry in both sides of the lower mould mold core that is equipped with is provided with the lower mould fin, and the lower mould fin is the array and covers on the both ends lateral wall of lower mould mold core to in the middle of the same sealing connection of lower mould fin in the inner chamber of cooling lower bolster, this structural design is favorable to in the middle of the inner chamber cooling water of leading-in cooling lower bolster fast with the both sides heat of lower mould mold core through the lower mould fin, effectively improves the radiating efficiency of lower mould mold core.

The lower mould core both ends lateral wall that is equipped with all has seted up the recirculated cooling water chamber, and this recirculated cooling water chamber all is linked together through the inner chamber of cooling water circulating pipe with the cooling lower bolster, is favorable to pouring into the recirculated cooling water chamber into rapidly through the cooling water circulating pipe in the middle of to realize constantly circulative cooling and operate, thereby the heat dispersion of better quickening lower mould core.

The cooling water chamber has also been seted up to the last mould cooling plate inside that is equipped with, and goes up the mould cooling plate bilateral symmetry and be provided with the cooling water and insert the pipe to go up the mould cooling plate and insert the pipe through the cooling water and be linked together with external cooling device, be favorable to inserting the quick inner chamber of mould cooling plate in the middle of pouring into of managing the cooling water through the cooling water, thereby better dispel the heat for last mould core.

Last mould core that is equipped with is fixed to be set up on the downside terminal surface of last mould cooling plate, and goes up the top side terminal surface of mould core and go up the array and be provided with the mould core and support the heating panel to go up the mould core and support on the inner chamber top surface of last mould cooling plate through the mould core, the design that the mould core supported the heating panel is firstly favorable to playing a supporting effect to last mould core, secondly can accelerate the radiating effect of last mould core, improves the effect of heat dispersion.

The rectangle breach has been seted up to equal symmetry on the both ends medial surface of last fixed plate of mould and lower mould fixed plate that is equipped with, and the cooling water inserts the pipe and all is connected with external cooling device through this breach, and this kind of design does benefit to the cooling water and inserts the pipe and the installation of being connected of outside cooling device, improves the installation convenience performance.

Drawings

FIG. 1 is a schematic three-dimensional structure of the present invention;

FIG. 2 is a schematic view of a three-dimensional split structure according to the present invention;

FIG. 3 is a schematic view of the three-dimensional split bottom structure of the present invention;

FIG. 4 is a schematic three-dimensional structure of a lower mold fixing plate according to the present invention;

FIG. 5 is a schematic three-dimensional structure of a lower stamping die according to the present invention;

FIG. 6 is a schematic cross-sectional three-dimensional structure view of a lower stamping die according to the present invention;

FIG. 7 is a schematic cross-sectional three-dimensional structure view of a lower die core of the present invention;

FIG. 8 is a schematic three-dimensional structure of an upper mold fixing plate according to the present invention;

FIG. 9 is a schematic three-dimensional structure of an upper mold core according to the present invention;

FIG. 10 is a schematic cross-sectional three-dimensional structure diagram of an upper mold core according to the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. an upper die fixing plate; 2. a lower die fixing plate; 3. stamping a lower die; 301. cooling the lower template; 302. a cooling water circulation pipe; 303. a lower die radiating fin; 304. a lower die core; 305. supporting the heat dissipation column; 306. a circulating cooling water cavity; 4. stamping an upper die; 401. an upper die core; 402. an upper die cooling plate; 403. the mold core supports the heat dissipation plate; 5. and a cooling water inlet pipe.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 10:

the invention provides a matched cooling tank structure based on a stamping die, which comprises: the device comprises an upper die fixing plate 1, a lower die fixing plate 2, a stamping lower die 3, a cooling lower die plate 301, a cooling water circulating pipe 302, a lower die cooling fin 303, a lower die core 304, a supporting heat dissipation column 305, a circulating cooling water cavity 306, a stamping upper die 4, an upper die core 401, an upper die cooling plate 402, a die core supporting heat dissipation plate 403 and a cooling water access pipe 5; an upper stamping die 4 is fixedly mounted on the inner side of the upper die fixing plate 1 through bolts, and the upper stamping die 4 consists of an upper die core 401, an upper die cooling plate 402 and a die core supporting heat dissipation plate 403; the stamping lower die 3 is fixedly installed on the inner side of the lower die fixing plate 2 through bolts, and the stamping lower die 3 consists of a cooling lower die plate 301, a cooling water circulating pipe 302, lower die cooling fins 303, a lower die core 304, a supporting cooling column 305 and a circulating cooling water cavity 306; the upper die core 401 and the lower die core 304 are designed correspondingly; the upper die fixing plate 1 is correspondingly installed on the upper side of the lower die fixing plate 2, and the upper die fixing plate 1 and the lower die fixing plate 2 are connected in a sliding mode through guide posts.

Wherein, the cooling water cavity has been seted up to the inside of cooling lower bolster 301, and the left and right sides of cooling lower bolster 301 all communicates and is provided with cooling water access pipe 5, and cooling water access pipe 5 is connected with external cooling device, is convenient for insert the cooling water fast into cooling lower bolster 301 inner chamber in the middle of through cooling water access pipe 5 to realize the rapid cooling operation to punching press lower mould 3, according to fig. 5 shown.

Wherein, the lower die core 304 is arranged on the top end surface of the cooling lower die plate 301, and the bottom side array of the lower die core 304 is provided with a plurality of supporting heat dissipation columns 305, and the lower die core 304 is supported on the bottom end surface of the inner cavity of the cooling lower die plate 301 through the supporting heat dissipation columns 305, and the supporting heat dissipation columns 305 are made of copper materials, the design of the supporting heat dissipation columns 305 is convenient for effectively supporting the lower die core 304, and can increase the heat dissipation effect of the lower die core 304, and the design of the supporting heat dissipation columns 305 for the copper columns enables the heat dissipation of the lower die core 304 to be more rapid and uniform, as shown in fig. 5.

The two sides of the lower die core 304 are symmetrically provided with lower die cooling fins 303, the lower die cooling fins 303 cover the side walls of the two ends of the lower die core 304 in an array manner, and the lower die cooling fins 303 are also hermetically connected in the inner cavity of the lower cooling plate 301, the structural design facilitates the heat on the two sides of the lower die core 304 to be rapidly led into the cooling water in the inner cavity of the lower cooling plate 301 through the lower die cooling fins 303, and the heat dissipation efficiency of the lower die core 304 is effectively improved, as shown in fig. 6-7.

Wherein, the side walls of the two ends of the lower mold core 304 are both provided with circulating cooling water cavities 306, and the circulating cooling water cavities 306 are communicated with the inner cavity of the cooling lower template 301 through the cooling water circulating pipe 302, so that cooling water can be rapidly injected into the circulating cooling water cavities 306 through the cooling water circulating pipe 302, and continuous circulating cooling operation is realized, thereby better accelerating the heat dissipation performance of the lower mold core 304, as shown in fig. 7.

Wherein, go up inside the same cooling water chamber of having seted up of mould cooling plate 402, and go up mould cooling plate 402 bilateral symmetry and be provided with cooling water access pipe 5 to it is linked together with external cooling device through cooling water access pipe 5 to go up mould cooling plate 402, is convenient for insert the inner chamber of mould cooling plate 402 in the middle of the quick injection of cooling water access pipe 5, thereby better for going up mould core 401 and dispel the heat, according to fig. 9 shown.

Wherein, go up mould core 401 and fix and set up on the downside terminal surface of last mould cooling plate 402, and go up the top side terminal surface of mould core 401 and the array is provided with mould core support heating panel 403, and go up mould core 401 and support on the inner chamber top surface of last mould cooling plate 402 through mould core support heating panel 403, the design of mould core support heating panel 403 is firstly convenient for play a supporting effect to last mould core 401, secondly can accelerate the radiating effect of last mould core 401, improves the effect of heat dispersion, as shown in fig. 10.

Wherein, the rectangle breach has all been seted up to the symmetry on the both ends medial surface of upper die fixing plate 1 and lower mould fixed plate 2, and cooling water inserts pipe 5 and all is connected with external cooling device through this breach, and this kind of design is convenient for cooling water inserts pipe 5 and outside cooling device's the installation of being connected, improves the installation convenience performance.

The specific use mode and function of the embodiment are as follows:

when using this supporting cooling bath structure of cooling down based on stamping die, at first need carry out the die sinking according to the design drawing of this mould, assemble after the die sinking is accomplished, alright use after the equipment is accomplished, earlier insert cooling water access tube 5 with cooling device's connecting pipe during use, then alright carry out the punching press and use, during the punching press cooling water can pour into earlier in the middle of the inner chamber of cooling lower bolster 301 and last mould cooling plate 402 into, then distribute away the heat through the support heat dissipation post 305 that sets up and lower mould fin 303 and mold core support heat dissipation plate 403 is quick, thereby play the quick refrigerated effect of mould, and the cooling water circulating pipe 302 that sets up can also circulate the cooling water in recirculated cooling water cavity 306, thereby play the effect of diversified heat dissipation cooling, effectively improve the radiating efficiency.

In summary, although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the technical solutions described in the foregoing embodiments or equivalent substitutions for some technical features, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. The utility model provides a supporting cooling tank structure of cooling based on stamping die which characterized in that: the matched cooling tank structure based on the stamping die comprises an upper die fixing plate (1), a lower die fixing plate (2), a stamping lower die (3), a cooling lower die plate (301), a cooling water circulating pipe (302), a lower die cooling fin (303), a lower die core (304), a supporting cooling column (305), a circulating cooling water cavity (306), a stamping upper die (4), an upper die core (401), an upper die cooling plate (402), a die core supporting cooling plate (403) and a cooling water access pipe (5); an upper stamping die (4) is fixedly mounted on the inner side of the upper die fixing plate (1) through bolts, and the upper stamping die (4) consists of an upper die core (401), an upper die cooling plate (402) and a core supporting heat dissipation plate (403); the stamping lower die (3) is fixedly installed on the inner side of the lower die fixing plate (2) through bolts, and the stamping lower die (3) is composed of six parts, namely a cooling lower die plate (301), a cooling water circulating pipe (302), a lower die cooling fin (303), a lower die core (304), a supporting cooling column (305) and a circulating cooling water cavity (306); the upper die core (401) and the lower die core (304) are designed correspondingly; the upper die fixing plate (1) is correspondingly arranged on the upper side of the lower die fixing plate (2), and the upper die fixing plate (1) is connected with the lower die fixing plate (2) in a sliding manner through a guide column;

a cooling water cavity is formed in the lower cooling template (301), cooling water inlet pipes (5) are communicated with the left side and the right side of the lower cooling template (301), and the cooling water inlet pipes (5) are connected with an external cooling device;

the lower die core (304) is arranged on the top end face of the lower cooling template (301), a plurality of supporting heat dissipation columns (305) are arranged on the bottom side array of the lower die core (304), the lower die core (304) is supported on the bottom end face of the inner cavity of the lower cooling template (301) through the supporting heat dissipation columns (305), and the supporting heat dissipation columns (305) are made of copper materials;

the two sides of the lower die mold core (304) are symmetrically provided with lower die cooling fins (303), the lower die cooling fins (303) cover the side walls of the two ends of the lower die mold core (304) in an array manner, and the lower die cooling fins (303) are also hermetically connected in the inner cavity of the lower cooling template (301);

the side walls of two ends of the lower die core (304) are respectively provided with a circulating cooling water cavity (306), and the circulating cooling water cavities (306) are communicated with the inner cavity of the lower cooling template (301) through cooling water circulating pipes (302);

a cooling water cavity is also formed in the upper die cooling plate (402), cooling water access pipes (5) are symmetrically arranged on two sides of the upper die cooling plate (402), and the upper die cooling plate (402) is communicated with an external cooling device through the cooling water access pipes (5);

the upper die core (401) is fixedly arranged on the lower side end face of the upper die cooling plate (402), the top side end face of the upper die core (401) is provided with die core supporting heat dissipation plates (403) in an array mode, and the upper die core (401) is supported on the top face of the inner cavity of the upper die cooling plate (402) through the die core supporting heat dissipation plates (403);

rectangular notches are symmetrically formed in the end faces of the inner sides of the two ends of the upper die fixing plate (1) and the lower die fixing plate (2), and the cooling water inlet pipe (5) is connected with an external cooling device through the notches.