CN213687495U - Magnesium alloy part molding heat dissipation device - Google Patents

Abstract

The utility model discloses a magnesium alloy part shaping heat abstractor, including box one, heat conduction layer board and camera, be provided with in the box one the heat conduction layer board, the shaping article has been placed on the heat conduction layer board, heat conduction layer board bottom is provided with the heat conduction stick, be provided with on the lateral wall in the box one the camera, the camera top is provided with the air conditioning pipeline, be provided with the exhaust hole on the box one-to-one lateral wall, air conditioning pipeline one end is provided with the air-cooler. Has the advantages that: the utility model discloses a set up heat conduction layer board and heat conduction stick, the heat conduction layer board is used for dispelling the heat of shaping article bottom, has prevented that local heat dissipation is not good and lead to magnesium alloy spare the condition that the crack appears in magnesium alloy spare forming process, and the heat conduction stick is used for leading away the heat of heat conduction layer board, and then increases the heat conduction effect of heat conduction layer board, improves the device functionality.

Description

Magnesium alloy part molding heat dissipation device

Technical Field

The utility model relates to a heat abstractor technical field, concretely relates to magnesium alloy spare shaping heat abstractor.

Background

The magnesium alloy is formed by adding other elements into magnesium as a base, and has the advantages of high strength, large elastic modulus, good heat dissipation, good shock absorption, larger impact load bearing capacity than aluminum alloy, and good organic matter and alkali corrosion resistance. The main alloy elements comprise aluminum, zinc, manganese, cerium, thorium, a small amount of zirconium or cadmium and the like. Currently, the most widely used are magnesium-aluminum alloys, followed by magnesium-manganese alloys and magnesium-zinc-zirconium alloys. The method is mainly used in aviation, aerospace, transportation, chemical engineering, rocket and other industrial departments. The lightest metal in practical metal, magnesium has specific gravity of about 2/3 of aluminum and 1/4 of iron, and is the lightest metal in practical metal, and has high strength and high rigidity.

When the existing magnesium alloy part forming heat dissipation device dissipates heat, the part of the magnesium alloy part, which is contacted with the supporting plate, cannot be quickly dissipated, so that the local heat dissipation effect of the magnesium alloy part is poor easily, the crack condition occurs locally in the forming process, and the device functionality is reduced.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

In order to overcome the defects of the prior art, the magnesium alloy part forming heat dissipation device is provided, and the problems that the existing magnesium alloy part forming heat dissipation device cannot rapidly dissipate heat of a part, contacted with a supporting plate, of a magnesium alloy part when dissipating heat, so that local heat dissipation of the magnesium alloy part is easily caused, the whole temperature difference of the magnesium alloy part is large, the occurrence of a crack condition is locally generated in the forming process, the device functionality is reduced, and the existing magnesium alloy part forming heat dissipation device is used, the internal condition cannot be monitored due to the fact that the sight of a box door blocks, when the formed part has problems, the problems cannot be effectively found in time and corresponding treatment is carried out, and the device practicability is reduced are solved.

(II) technical scheme

The utility model discloses a following technical scheme realizes: including box one, heat conduction layer board and camera, be provided with in the box one the heat conduction layer board, the shaping article has been placed on the heat conduction layer board, heat conduction layer board bottom is provided with the heat conduction stick, be provided with on the lateral wall in the box one the camera, the camera top is provided with the air conditioning pipeline, be provided with the exhaust hole on the box one lateral wall, air conditioning pipeline one end is provided with the air-cooler, box one outer wall one side is provided with the pivot, be provided with the chamber door in the pivot, box below is provided with box two, be provided with the display screen on the two lateral walls of box, the display screen below is provided with operating panel, be provided with the exhaust fan on the other lateral wall of box two, box two with be provided with the inlet port on the relative lateral wall of exhaust fan, box two below is provided with the.

Furthermore, the heat conducting supporting plate is connected with the first box body through screws, the heat conducting rod is connected with the heat conducting supporting plate through screws, and the heat conducting rod penetrates through the first box body and the second box body.

By adopting the technical scheme, the heat conducting supporting plate is used for dissipating heat of the bottom of the formed product, so that local heat dissipation in the forming process of the magnesium alloy part is prevented, and therefore the condition of cracks is avoided.

Furthermore, the camera is connected with the first box body through a screw.

By adopting the technical scheme, the camera is used for observing whether local forming distortion, cracks and other conditions occur in the forming process of the magnesium alloy part, so that corresponding measures can be taken by workers in advance to avoid causing unnecessary loss.

Further, the air conditioning pipeline with box one is connected through the draw-in groove, the exhaust hole shaping in box one is last, the air-cooler with box one is through the screw connection, the air conditioning pipeline with the air-cooler is pegged graft.

By adopting the technical scheme, the air cooler is used for blowing out cold air, the cold air pipeline is used for transmitting the cold air discharged by the air cooler to the inside of the first box body, the exhaust holes are used for discharging hot air in the inside of the first box body, and the combination of the cold air pipeline, the air cooler and the exhaust holes can enable the first box body to achieve a better heat dissipation effect.

Furthermore, the rotating shaft is connected with the first box body through a screw, and the box door is rotatably connected with the rotating shaft.

By adopting the technical scheme, the rotating shaft is used for opening and closing the box door, and the box door is used for preventing dust from entering the first box body.

Furthermore, the second box body is connected with the first box body through screws, the display screen is connected with the second box body through screws, and the operation panel is connected with the second box body through screws.

By adopting the technical scheme, the second box body is used for hiding the heat conducting rod, certain protection is carried out on workers, scalding by the heat conducting rod is prevented, and the display screen is used for displaying images in the forming process of the magnesium alloy part monitored by the camera.

Furthermore, the exhaust fan is connected with the second box body through screws, the air inlet is formed in the second box body, and the base is connected with the second box body through screws.

By adopting the technical scheme, the exhaust fan is used for discharging heat of the heat conducting rod in the second box body, the air inlet is used for enabling outside air to enter the second box body, the air inlet and the air outlet are combined to form circulation of air in the second box body, and the base is used for increasing the stress area of the second box body.

(III) advantageous effects

Compared with the prior art, the utility model, following beneficial effect has:

1. in order to solve the problems that the existing magnesium alloy part forming and radiating device can not quickly radiate the contact part of the magnesium alloy part and the supporting plate when radiating heat, thereby easily causing poor local radiating effect of the magnesium alloy part and causing the occurrence of cracks locally in the forming process and reducing the functionality of the device, the utility model discloses a heat conducting supporting plate and a heat conducting rod are arranged, the heat conducting supporting plate is used for radiating the heat at the bottom of a formed product, thereby preventing the crack of the magnesium alloy part caused by poor local radiating in the forming process of the magnesium alloy part, and the heat conducting rod is used for conducting the heat of the heat conducting supporting plate out, thereby increasing the heat conducting effect of the heat conducting supporting plate and improving the functionality of the device;

2. for solving current magnesium alloy spare shaping heat abstractor when using, because the sight of chamber door blocks, can't watch on the inside condition, when the formed part goes wrong, can't effectual in time discover the problem and make corresponding processing, the problem of reduction device practicality, the utility model discloses a display screen and camera, camera are used for observing whether appear the emergence of the condition such as local shaping distortion and cracks in the magnesium alloy spare forming process, and the display screen is used for showing the image that the camera mapped in the magnesium alloy spare forming process, can make the staff make corresponding measure in advance to avoid causing the unnecessary loss, improve the device practicality.

Drawings

Fig. 1 is a schematic structural diagram of a magnesium alloy part forming heat dissipation device of the present invention;

FIG. 2 is a left side view of the magnesium alloy part forming heat sink of the present invention;

FIG. 3 is a cross-sectional view of a first box and a second box of the magnesium alloy part forming heat dissipation device of the present invention;

the reference numerals are explained below:

1. a first box body; 2. an exhaust hole; 3. a molded article; 4. an air cooler; 5. a heat conducting support plate; 6. an air inlet; 7. a base; 8. an operation panel; 9. a display screen; 10. a heat conducting rod; 11. a camera; 12. a box door; 13. a rotating shaft; 14. a cold air duct; 15. an exhaust fan; 16. and a second box body.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1-3, the magnesium alloy part forming and heat dissipating device in this embodiment includes a first box 1, a heat conducting supporting plate 5 and a camera 11, the first box 1 is provided with the heat conducting supporting plate 5, the formed product 3 is placed on the heat conducting supporting plate 5, the bottom end of the heat conducting supporting plate 5 is provided with a heat conducting rod 10, the heat conducting supporting plate 5 is used for dissipating heat from the bottom of the formed product 3, so as to prevent local heat dissipation in the forming process of the magnesium alloy part, thereby causing cracks, the heat conducting rod 10 is used for conducting out heat from the heat conducting supporting plate 5, so as to increase the heat conducting effect of the heat conducting supporting plate 5, the camera 11 is arranged on one inner side wall of the first box 1, the camera 11 is used for observing whether local forming distortion and cracks occur in the forming process of the magnesium alloy part, so as to enable a worker to take corresponding measures in advance, thereby, an air-conditioning duct 14 is arranged above the camera 11, an exhaust hole 2 is arranged on one side wall of the first box body 1, an air cooler 4 is arranged at one end of the air-conditioning duct 14, the air cooler 4 is used for blowing out cold air, the air-conditioning duct 14 is used for transmitting the cold air discharged by the air cooler 4 into the first box body 1, the exhaust hole 2 is used for discharging hot air in the first box body 1, the three parts are combined to enable the first box body 1 to achieve a better heat dissipation effect, a rotating shaft 13 is arranged on one side of the outer wall of the first box body 1, a box door 12 is arranged on the rotating shaft 13, the rotating shaft 13 is used for opening and closing the box door 12, the box door 12 is used for preventing dust from entering the first box body 1, a second box body 16 is arranged below the first box body 1, a display screen 9 is arranged on one side wall of the second box body 16, an operation panel 8 is arranged below, prevent to be scalded by heat conduction stick 10, display screen 9 is used for showing the image of the magnesium alloy spare forming process that camera 11 was monitored, be provided with exhaust fan 15 on the other lateral wall of box two 16, be provided with inlet port 6 on box two 16 and the relative lateral wall of exhaust fan 15, box two 16 belows are provided with base 7, exhaust fan 15 is used for discharging away the heat of the inside heat conduction stick 10 of box two 16, inlet port 6 is used for making inside external air admission box two 16, the two combines the circulation that forms the inside air of box two 16, base 7 is used for increasing the lifting surface area of box two 16.

As shown in fig. 1 to fig. 3, in this embodiment, the heat conducting supporting plate 5 is connected to the first box 1 through screws, the heat conducting rod 10 is connected to the heat conducting supporting plate 5 through screws, the heat conducting rod 10 penetrates through the first box 1 and the second box 16, the camera 11 is connected to the first box 1 through screws, the air cooling duct 14 is connected to the first box 1 through a clamping groove, the exhaust hole 2 is formed in the first box 1, the air cooler 4 is connected to the first box 1 through screws, and the air cooling duct 14 is connected to the air cooler 4 in an inserting manner.

As shown in fig. 1-3, in the embodiment, the rotating shaft 13 is connected to the first box 1 by screws, the box door 12 is connected to the rotating shaft 13 by screws, the second box 16 is connected to the first box 1 by screws, the display screen 9 is connected to the second box 16 by screws, the operation panel 8 is connected to the second box 16 by screws, the exhaust fan 15 is connected to the second box 16 by screws, the air inlet 6 is formed in the second box 16, and the base 7 is connected to the second box 16 by screws.

The specific implementation process of this embodiment is as follows: firstly, opening a box door 12, placing a formed product 3 on a heat conducting supporting plate 5, then closing the box door 12, preventing dust and micro particles from entering a box body I1 to influence the forming of the formed product 3, then operating a cooling fan 4 and an exhaust fan 15 through a control button on an operation panel 8, wherein the cooling fan 4 is used for blowing cold air, a cold air pipeline 14 is used for transmitting the cold air discharged by the cooling fan 4 to the interior of the box body I1, an exhaust hole 2 is used for discharging hot air in the interior of the box body I1, the combination of the three can enable the box body I1 to achieve better heat dissipation effect, then guiding the heat of the heat conducting supporting plate 5 into a box body II 16 through a heat conducting rod 10, then discharging the heat emitted by the heat conducting rod 10 in the box body II 16 through the exhaust fan 15, then enabling outside air to enter the interior of the box body II 16 through an air inlet hole 6, and accelerating the circulation of the, finally, the display screen 9 is used for displaying the image of the magnesium alloy part monitored by the camera 11 in the forming process to observe whether the local forming distortion, cracks and other conditions occur in the forming process of the magnesium alloy part, so that the working personnel can take corresponding measures in advance to avoid unnecessary loss.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and are not intended to limit the spirit and scope of the present invention. Without departing from the design concept of the present invention, various modifications and improvements made by the technical solution of the present invention by those skilled in the art should fall into the protection scope of the present invention, and the technical contents claimed by the present invention have been fully recorded in the claims.

Claims (7)

1. A magnesium alloy part molding heat dissipation device is characterized in that: comprises a first box body (1), a heat-conducting supporting plate (5) and a camera (11), wherein the heat-conducting supporting plate (5) is arranged in the first box body (1), a formed product (3) is placed on the heat-conducting supporting plate (5), a heat-conducting rod (10) is arranged at the bottom end of the heat-conducting supporting plate (5), the camera (11) is arranged on one side wall in the first box body (1), an air-cooling pipeline (14) is arranged above the camera (11), an exhaust hole (2) is arranged on one side wall of the first box body (1), an air cooler (4) is arranged at one end of the air-cooling pipeline (14), a rotating shaft (13) is arranged on one side of the outer wall of the first box body (1), a box door (12) is arranged on the rotating shaft (13), a second box body (16) is arranged below the first box body (1), a display screen (9) is arranged on one side wall of the second box, an exhaust fan (15) is arranged on the other side wall of the second box body (16), an air inlet hole (6) is formed in the side wall, opposite to the exhaust fan (15), of the second box body (16), and a base (7) is arranged below the second box body (16).

2. The magnesium alloy part forming heat dissipation device according to claim 1, characterized in that: the heat conduction supporting plate (5) is connected with the first box body (1) through screws, the heat conduction rod (10) is connected with the heat conduction supporting plate (5) through screws, and the heat conduction rod (10) penetrates through the first box body (1) and the second box body (16).

3. The magnesium alloy part forming heat dissipation device according to claim 1, characterized in that: the camera (11) is connected with the first box body (1) through a screw.

4. The magnesium alloy part forming heat dissipation device according to claim 1, characterized in that: air conditioning pipeline (14) with box (1) is connected through the draw-in groove, exhaust hole (2) shaping in on box (1), air-cooler (4) with box (1) is through the screw connection, air conditioning pipeline (14) with air-cooler (4) are pegged graft.

5. The magnesium alloy part forming heat dissipation device according to claim 1, characterized in that: the rotating shaft (13) is connected with the first box body (1) through a screw, and the box door (12) is rotatably connected with the rotating shaft (13).

6. The magnesium alloy part forming heat dissipation device according to claim 1, characterized in that: the second box body (16) is connected with the first box body (1) through screws, the display screen (9) is connected with the second box body (16) through screws, and the operation panel (8) is connected with the second box body (16) through screws.

7. The magnesium alloy part forming heat dissipation device according to claim 1, characterized in that: the exhaust fan (15) is connected with the second box body (16) through screws, the air inlet holes (6) are formed in the second box body (16), and the base (7) is connected with the second box body (16) through screws.

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