CN220586735U - High-performance graphite block capable of ventilating and cooling - Google Patents

Abstract

The utility model discloses a ventilated cooling high-performance graphite block which comprises a graphite frame, wherein a clamping groove is formed in the graphite frame, a graphite plate is arranged on the outer wall of the graphite frame, a plugboard is fixedly connected to the outer wall of the graphite plate, the plugboard is connected with the clamping groove in a sleeved mode, a metal sleeve is fixedly connected to the inner portion of the plugboard, a connecting pin is connected to the inner thread of the metal sleeve, a heat dissipation groove is formed in the inner portion of the graphite plate, and heat dissipation holes are formed in the outer wall of the heat dissipation groove in a communicating mode. The utility model relates to the technical field of graphite blocks, in particular to a high-performance graphite block capable of ventilating and cooling.

Description

High-performance graphite block capable of ventilating and cooling

Technical Field

The utility model relates to the technical field of graphite blocks, in particular to a high-performance graphite block capable of ventilating and cooling.

Background

Graphite blocks are a graphite product commonly used in a variety of industrial applications. They are made of high purity graphite, which has the characteristics of high thermal conductivity, low resistance, oxidation resistance, corrosion resistance, etc., and the high thermal conductivity of the graphite blocks enables them to withstand high temperatures and evenly distribute heat. This characteristic also makes them well suited for use in the construction of high temperature furnaces and other equipment where efficient heat transfer is required.

Wherein, when using graphite block conduction material, can set up the through-hole in graphite block's inside, for example, the application number is: according to the graphite block with the spiral V-shaped flow channel of CN202122193441.6, through the arrangement of the spiral V-shaped flow channel, the contact surface area of materials when entering is increased, the heat exchange utilization area of the graphite block is increased, the materials can rotate into the material holes along with the spiral, the materials can be distributed more uniformly, and the heat exchange effect of the graphite block is improved.

But the existing high-performance graphite block realizes heat exchange in the through holes in the graphite block, and the exchanged heat can be retained on the surface of the graphite block, and the surface cooling speed of the graphite block is slow due to the limited surface area of the graphite block.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a ventilated cooling high-performance graphite block, which solves the problems that the existing high-performance graphite block is low in cooling speed due to limited surface area of the graphite block because heat exchanged out of the material can be retained on the surface of the graphite block by realizing heat exchange in a through hole in the graphite block.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a but cooling high performance graphite block ventilates, includes the graphite frame, the inside processing of graphite frame has the draw-in groove, graphite plate is installed to the outer wall of graphite frame, the outer wall rigid coupling of graphite plate has the picture peg, picture peg and draw-in groove cup joint and link to each other, the inside rigid coupling of picture peg has the metal covering, the inside threaded connection of metal covering has the connecting pin, connecting pin and graphite frame cup joint and link to each other, the radiating groove has been seted up to the inside of graphite plate, the outer wall intercommunication of radiating groove has the louvre.

Preferably, the graphite plates are symmetrically distributed about the graphite frame.

Preferably, the heat dissipation grooves are equidistantly distributed along the graphite plate.

Preferably, the upper and lower both ends of graphite frame all process and have the through-hole, the internally mounted of graphite frame has the swash plate, the outer wall rigid coupling of swash plate has the fixture block, fixture block and graphite frame cup joint and link to each other, the top processing of graphite frame has the mounting groove, the bottom rigid coupling of graphite frame has the stopper.

Preferably, the limiting block and the mounting groove are positioned on the same vertical line.

Compared with the prior art, the utility model has the beneficial effects that: compared with the prior art, the ventilated cooling high-performance graphite block has the following advantages:

through the cooperation of the graphite frame, the clamping groove, the graphite plate, the plugboard, the metal sleeve, the connecting pin, the heat dissipation groove, the heat dissipation holes and the like, the plugboard on the outer wall of the graphite plate is inserted into the clamping groove, then the connecting pin in the graphite frame is rotated to be inserted into the metal sleeve in the plugboard, the installation of the graphite plate is completed, heat is transferred to the surface of the graphite plate, the heat dissipation groove increases the surface area of the graphite plate, and a plurality of heat dissipation holes communicated with the heat dissipation groove are convenient for air to flow in from different directions, so that the heat dissipation efficiency of the graphite plate is accelerated;

through the cooperation use of through-hole, swash plate, fixture block, mounting groove and stopper etc., the setting of stopper and mounting groove is convenient for connect between two graphite framves, inserts the inside of graphite frame through the fixture block, and then installs the swash plate, and the raw materials enters into the inside of graphite frame through the through-hole at top, increases the residence time of raw materials in the graphite frame through crisscross swash plate, and then guarantees to have sufficient heat transfer time between raw materials and the graphite board.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the connection structure of the graphite plate, the insert plate and the metal sleeve in FIG. 1;

FIG. 3 is a schematic view of a connection structure of the graphite frame, the clamping block and the sloping plate in FIG. 1;

fig. 4 is a schematic diagram of a connection structure of the graphite frame, the mounting groove and the stopper in fig. 1.

In the figure: 1. the graphite frame, 2, the draw-in groove, 3, graphite sheet, 4, picture peg, 5, metal sheath, 6, connecting pin, 7, heat dissipation groove, 8, the louvre, 9, through-hole, 10, swash plate, 11, fixture block, 12, mounting groove, 13, stopper.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The existing high-performance graphite block is characterized in that heat exchange is realized in a through hole in the graphite block by materials, heat exchanged out can be retained on the surface of the graphite block, and the problem that the surface cooling speed of the graphite block is low is caused due to the limited surface area of the graphite block.

In view of the above, the utility model provides a ventilated cooling high-performance graphite block, which is characterized in that through the cooperation of a graphite frame, a clamping groove, a graphite plate, an inserting plate, a metal sleeve, a connecting pin, a heat dissipation groove, a heat dissipation hole and the like, the inserting plate on the outer wall of the graphite plate is inserted into the clamping groove, then the connecting pin in the graphite frame is rotated to be inserted into the metal sleeve in the inserting plate, the installation of the graphite plate is completed, heat is transferred to the surface of the graphite plate, the surface area of the graphite plate is increased by the heat dissipation groove, and a plurality of heat dissipation holes communicated with the heat dissipation groove are convenient for air to flow in from different directions, so that the heat dissipation efficiency of the graphite plate is accelerated.

As can be seen from fig. 1, 2 and 3, the aerated high-performance graphite block comprises a graphite frame 1, wherein a clamping groove 2 is processed in the graphite frame 1, a graphite plate 3 is arranged on the outer wall of the graphite frame 1, a plugboard 4 is fixedly connected to the outer wall of the graphite plate 3, the plugboard 4 is connected with the clamping groove 2 in a sleeved mode, a metal sleeve 5 is fixedly connected to the inner portion of the plugboard 4, a connecting pin 6 is connected to the inner thread of the metal sleeve 5 in a threaded mode, the connecting pin 6 is connected with the graphite frame 1 in a sleeved mode, a heat dissipation groove 7 is formed in the graphite plate 3, and heat dissipation holes 8 are formed in the outer wall of the heat dissipation groove 7 in a communicated mode;

in the specific implementation process, it is worth particularly pointing out that the graphite frame 1 is made of graphite materials, four clamping grooves 2 are machined in the graphite frame 1, two plugboards 4 are fixedly connected to the outer wall of each graphite plate 3, two metal sleeves 5 are inlaid in the plugboards 4, internal threads are machined in the metal sleeves 5, threads are machined on the outer wall of the connecting pin 6, the plugboards 4 are fixed in the graphite frame 1 by the connecting pin 6, the using position of the graphite plate 3 is further determined, the surface area of the graphite plate 3 is increased by the aid of the rectangular through grooves, the air circulation speed in the heat dissipation grooves 7 is increased by the aid of the circular heat dissipation holes 8, and therefore heat dissipation of the graphite plate 3 is achieved;

further, the graphite sheets 3 are symmetrically distributed about the graphite frame 1;

in the specific implementation, it is worth particularly pointing out that the two graphite plates 3 close the two sides of the graphite frame 1;

specifically, install two graphite sheets 3 in the both sides of graphite frame 1, the picture peg 4 of graphite sheet 3 outer wall inserts draw-in groove 2, connecting pin 6 in the later rotation graphite frame 1, connecting pin 6 inserts in the inside metal sheath 5 of picture peg 4, and then the position of fixed picture peg 4, accomplish the installation of graphite sheet 3 simultaneously, the heat transfer reaches the surface of graphite sheet 3, the surface area of graphite sheet 3 is increased to the heat dissipation groove 7, the setting of a plurality of louvres 8 with the heat dissipation groove 7 intercommunication is convenient for the air inflow from different directions for the radiating efficiency of graphite sheet 3.

As can be seen from fig. 1, 3 and 4, the heat dissipation grooves 7 are equidistantly distributed along the graphite plate 3;

in the specific implementation process, it is worth particularly pointing out that the arrangement of the plurality of heat dissipation grooves 7 increases the surface area of the graphite plate 3 and increases the heat exchange area with the air;

further, through holes 9 are formed in the upper end and the lower end of the graphite frame 1, an inclined plate 10 is arranged in the graphite frame 1, a clamping block 11 is fixedly connected to the outer wall of the inclined plate 10, the clamping block 11 is connected with the graphite frame 1 in a sleeved mode, an installation groove 12 is formed in the top of the graphite frame 1, and a limiting block 13 is fixedly connected to the bottom of the graphite frame 1;

in the specific implementation process, it is worth particularly pointing out that the arrangement of the through holes 9 is convenient for the inflow and outflow of raw materials, three inclined plates 10 are arranged in a staggered manner, clamping blocks 11 can be embedded into the inner wall of the graphite frame 1 for fixing the inclined plates 10, two mounting grooves 12 are arranged, two limiting blocks 13 are arranged, and the inclined plates 10 increase the residence time of the raw materials in the graphite frame 1;

further, the limiting block 13 and the mounting groove 12 are positioned on the same vertical line;

in the specific implementation process, it is worth particularly pointing out that the limiting block 13 and the mounting groove 12 are convenient for the adjacent graphite frames 1 to be connected end to end, so that the combined use of the graphite frames 1 is facilitated;

specifically, on the basis of the above embodiment, the raw materials are inserted into the graphite frame 1 through the clamping blocks 11, then the inclined plates 10 are installed, the raw materials enter the graphite frame 1 through the through holes 9 at the top, the residence time of the raw materials in the graphite frame 1 is increased through the staggered inclined plates 10, and finally the raw materials are led out through the through holes 9 at the bottom, so that the connection between the two graphite frames 1 is facilitated by the limiting blocks 13 and the installation grooves 12.

In the description of the present utility model, it should be understood that the terms "coaxial," "bottom," "one end," "top," "middle," "another end," "upper," "one side," "top," "inner," "front," "center," "two ends," etc. indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "configured," "connected," "secured," "screwed," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intermediaries, or in communication with each other or in interaction with each other, unless explicitly defined otherwise, the meaning of the terms described above in this application will be understood by those of ordinary skill in the art in view of the specific circumstances.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a but high performance graphite piece of cooling down of ventilating, includes graphite frame (1), its characterized in that: the inside processing of graphite frame (1) has draw-in groove (2), graphite board (3) are installed to the outer wall of graphite frame (1), the outer wall rigid coupling of graphite board (3) has picture peg (4), picture peg (4) and draw-in groove (2) cup joint and link to each other, the inside rigid coupling of picture peg (4) has metal sheath (5), the inside threaded connection of metal sheath (5) has connecting pin (6), connecting pin (6) and graphite frame (1) cup joint and link to each other, radiating groove (7) have been seted up to the inside of graphite board (3), the outer wall intercommunication of radiating groove (7) has louvre (8).

2. The aerated, temperature-reduced, high performance graphite block of claim 1, wherein: the graphite plates (3) are symmetrically distributed about the graphite frame (1).

3. The aerated, temperature-reduced, high performance graphite block of claim 1, wherein: the heat dissipation grooves (7) are distributed along the graphite plate (3) at equal intervals.

4. The aerated, temperature-reduced, high performance graphite block of claim 1, wherein: the upper end and the lower end of the graphite frame (1) are respectively provided with a through hole (9), the inside of the graphite frame (1) is provided with a sloping plate (10), the outer wall of the sloping plate (10) is fixedly connected with a clamping block (11), the clamping block (11) is connected with the graphite frame (1) in a sleeved mode, the top of the graphite frame (1) is provided with a mounting groove (12), and the bottom of the graphite frame (1) is fixedly connected with a limiting block (13).

5. The aerated, temperature-reduced, high performance graphite block of claim 4, wherein: the limiting block (13) and the mounting groove (12) are positioned on the same vertical line.