CN216804133U - Mould processing and cooling device - Google Patents

Abstract

The utility model provides a mould processing and cooling device, includes elevating platform, heating coil, cooling frame and blast pipe, heating coil is the annular, the elevating platform is used for promoting the mould to get into heating coil's inner ring, the downside of cooling frame be equipped with the joint extremely the draw-in groove on heating coil's upper portion, the cooling frame includes the butt extremely heating coil's inner ring's cooling zone and butt extremely the support area of heating coil's outer ring, the cooling zone is equipped with the play wind groove that sets up down, go out the wind groove with heating coil's interior rampart parallels, the inside of cooling frame is equipped with airflow channel, the blast pipe is connected to the cooling frame, just it communicates in proper order to go out wind groove, airflow channel and blast pipe. The air current that blows off by the air-out groove is even stable among the above-mentioned scheme, has realized the regional quick cooling of inner ring to heating coil, and convenient simple to use possesses better practicality.

Description

Mould processing and cooling device

Technical Field

The utility model relates to the technical field of die machining equipment, in particular to a die machining and cooling device.

Background

The mold processing has been increasingly widely used in recent years due to the characteristics of high speed and low cost. In the actual production of part of the plate, the powder needs to be put into the die first, and then the whole die is heated and formed, so that the powder forms the required plate.

However, the temperature of the heated and formed mold is often high, and generally, the subsequent processing can be performed after the mold is primarily cooled, which causes time waste and affects the overall processing efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a die machining and cooling device capable of rapidly cooling a die after heat treatment.

In order to solve the problems, the utility model provides a die machining and cooling device which comprises a lifting platform, a heating coil, a cooling frame and an air supply pipe, wherein the heating coil is annular, the lifting platform is used for pushing a die to enter an inner ring of the heating coil, a clamping groove clamped to the upper part of the heating coil is arranged on the lower side surface of the cooling frame, the cooling frame comprises a cooling area abutted to the inner ring of the heating coil and a supporting area abutted to an outer ring of the heating coil, an air outlet groove arranged downwards is formed in the cooling area, the air outlet groove is parallel to the inner ring wall of the heating coil, an airflow channel is arranged in the cooling frame, the air supply pipe is connected to the cooling frame, and the air outlet groove, the airflow channel and the air supply pipe are sequentially communicated.

During the use, place the mould of treating processing on the elevating platform earlier, push into the inner ring of heating coil by the elevating platform with the mould afterwards and heat, treat the product thermoforming in the mould and accomplish the back, with the draw-in groove joint to the upper portion of heating coil of cooling frame to carry the cooling air current to airflow channel through the blast pipe, make the cooling air current blow off from the air-out groove, in order to realize the cooling to the inner ring's of heating coil mould. Compared with the prior art, the air current that blows off by the air-out groove among the above-mentioned scheme is even stable, has realized the quick cooling to the inner ring region of heating coil, and convenient to use, possesses better practicality.

Preferably, the heating coil is square, the two cooling frames are both L-shaped, and the two cooling frames are symmetrically arranged at the diagonal positions of the heating coil, so that even if the length and width of the heating coil are changed, the cooling frames can still be firmly clamped to the upper part of the heating coil, and the universality is good.

Preferably, the air supply pipe is connected to a bent position in the middle of the cooling rack, so that cooling air flows blown out from the air outlet grooves on two sides of the air supply pipe are more balanced.

Preferably, the air supply pipe is connected to the upper side surface of the cooling rack, the upper side wall of the airflow channel is provided with a partition plate, and the distance between the partition plate and the lower side wall of the airflow channel gradually increases along the direction away from the air supply pipe, so that the cooling airflow input into the airflow channel by the air supply pipe can be more uniformly blown out of the air outlet groove under the action of the partition plate.

Preferably, the partition is located in the supporting area, and further increases the stroke of the cooling air flow in the air flow channel, so that the cooling air flow is more stably blown out from the air outlet groove.

Drawings

FIG. 1 is a schematic front view of a mold tooling and cooling apparatus;

FIG. 2 is a schematic top view of a mold tooling and cooling apparatus (with the housing removed);

FIG. 3 is a schematic cross-sectional view taken along line A-A in FIG. 2;

fig. 4 is a schematic sectional view taken along line B-B in fig. 2.

Description of reference numerals:

b 1-lifting table; b 2-heating coil; b 3-cooling shelf; b 31-card slot; b 32-air outlet groove; b 33-airflow channel; b 34-baffle; b 4-blower tube.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention. It should be noted that all the directional indicators (such as up, down, left, right, front, back, inside, and outside) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the motion situation, and the like in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is changed accordingly.

Referring to fig. 1 to 4, a mold processing and cooling apparatus according to an embodiment of the present invention includes a lifting table b1, a heating coil b2, cooling rack b3 and blast pipe b4, heating coil b2 is ring-shaped and is located above elevating platform b1, elevating platform b1 is preferably driven by air cylinder to realize lifting, elevating platform b1 is used for pushing the mould to enter the inner ring of heating coil b2, the lower side of cooling rack b3 is provided with a clamping groove b31 clamped to the upper part of heating coil b2, cooling rack b3 comprises a cooling zone abutted to the inner ring of heating coil b2 and a supporting zone abutted to the outer ring of heating coil b2, the cooling zone is provided with a downward air outlet groove b32, air outlet groove b32 is parallel to the inner ring wall of heating coil b2, the inside of cooling rack b3 is provided with air flow channel b33, blast pipe b4 is connected to cooling rack b3, and air outlet groove b32, air flow channel b33 and blast pipe b4 are communicated in turn.

When the heating coil b2 is used, a die to be processed is placed on the lifting table b1, then the die is pushed into the inner ring of the heating coil b2 by the lifting table b1 to be heated, after the product in the die is subjected to thermoforming, the clamping grooves b31 of the cooling frame b3 are clamped to the upper portion of the heating coil b2, and cooling air flow is conveyed to the air flow channel b33 through the air supply pipe b4, so that the cooling air flow is blown out of the air outlet groove b32, and the cooling of the die of the inner ring of the heating coil b2 is achieved. Compared with the prior art, the air current that is blown out by air-out groove b32 is even stable among the above-mentioned scheme, has realized the quick cooling to the inner ring region of heating coil b2, and convenient to use, possesses better practicality.

In this embodiment, the heating coil b2 is preferably square, the two cooling racks b3 are both L-shaped, and the two cooling racks b3 are symmetrically arranged at diagonal positions of the heating coil b2, so that even if the length and width of the heating coil b2 are changed, the cooling rack b3 can be firmly clamped to the upper portion of the heating coil b2, and the versatility is good. It should be understood that the heating coil b2 may have other shapes such as a circle, a polygon and the like as needed, and the present design is not limited thereto.

As an optimization of the above embodiment, the blowing duct b4 is connected to the middle bent position of the cooling rack b3, so that the cooling air flow blown out from the air outlet grooves b32 positioned at both sides of the blowing duct b4 is more balanced.

Furthermore, the air supply pipe b4 is connected to the upper side surface of the cooling rack b3, the partition plate b34 is arranged on the upper side wall of the airflow channel b33, and the distance between the partition plate b34 and the lower side wall of the airflow channel b33 is gradually increased along the direction away from the air supply pipe b4, so that the cooling airflow input into the airflow channel b33 by the air supply pipe b4 can be more uniformly blown out of the air outlet groove b32 under the action of the partition plate b 34.

Further, the partition b34 is located in the supporting area, and the stroke of the cooling air flow in the air flow channel b33 is further promoted, so that the cooling air flow is more stably blown out of the air outlet groove b 32.

Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the disclosure, and these changes and modifications will fall within the scope of the utility model.

Claims (5)

1. A die machining and cooling device is characterized by comprising an elevating platform (b1), a heating coil (b2), a cooling rack (b3) and an air supply pipe (b4), wherein the heating coil (b2) is annular, the elevating platform (b1) is used for pushing a die to enter an inner ring of the heating coil (b2), the lower side surface of the cooling rack (b3) is provided with a clamping groove (b31) clamped to the upper part of the heating coil (b2), the cooling rack (b3) comprises a cooling area abutted to the inner ring of the heating coil (b2) and a supporting area abutted to the outer ring of the heating coil (b2), the cooling area is provided with an air outlet groove (b32) arranged downwards, the air outlet groove (b32) is parallel to the inner annular wall of the heating coil (b2), an air flow channel (b33) is arranged inside the cooling rack (b3), the air supply pipe (b4) is connected to the cooling rack (b3), and the air outlet groove (b32), the airflow channel (b33) and the blast pipe (b4) are communicated in sequence.

2. The mold processing and cooling device of claim 1, wherein said heating coil (b2) is square, said cooling racks (b3) are two and L-shaped, and two of said cooling racks (b3) are symmetrically arranged at the diagonal positions of said heating coil (b 2).

3. The mold processing and cooling device of claim 2, wherein the air supply duct (b4) is connected to the middle of the cooling frame (b3) at a bent position.

4. A mold processing and cooling apparatus as claimed in claim 3, wherein said air supply duct (b4) is connected to the upper side of said cooling frame (b3), the upper side wall of said air flow path (b33) is provided with a partition (b34), and the distance between said partition (b34) and the lower side wall of said air flow path (b33) is gradually increased in the direction away from said air supply duct (b 4).

5. A die working and cooling device according to claim 4, wherein said partition (b34) is located in said support area.

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