CN114144042A - High-frequency high-power 3D scene modeling model manufacturing terminal - Google Patents

Abstract

The invention discloses a high-frequency high-power 3D scene modeling model manufacturing terminal, which relates to the technical field of 3D modeling equipment, and comprises a heat dissipation box body and a modeling terminal equipment body, and further comprises: the heat dissipation assembly comprises a water cooling circulation component arranged on the outer side of the modeling terminal equipment body; the water-cooling circulation component comprises a water delivery pipe surrounding the outer side wall surface of the modeling terminal device body, the water delivery pipe is connected with the water tank through the circulation component, the circulation component conveys cooling water in the water tank to the water delivery pipe surrounding the outer side of the modeling terminal device body, the cooling water in the water delivery pipe cools and cools the modeling terminal device body, meanwhile, the blades are driven to rotate through a rotating mechanism arranged in the heat dissipation box body, the blades are used for accelerating the air flow rate of the peripheral side of the modeling terminal device body, the heat dissipation cooling effect of the modeling terminal device body is further improved, and the stable operation of the D scene modeling model manufacturing terminal device is guaranteed.

Description

High-frequency high-power 3D scene modeling model manufacturing terminal

Technical Field

The invention relates to the technical field of 3D modeling equipment, in particular to a high-frequency high-power 3D scene modeling model making terminal.

Background

With the development of computer vision technology and the emergence of depth cameras, 3D modeling technology, especially 3D modeling technology in large-scale scenes, brings important effects on navigation, city planning, environmental observation and the like, and the model is placed in a rendering engine, so that a picture with a 3D effect can be rendered offline or factually. The models are arranged in the scene to form the whole scene material, which is called as a construction scene, and the 3D artists generally use 3D modeling software to construct the scene material.

3D scene modeling model preparation terminal equipment is high frequency high power equipment, therefore has a large amount of dusts to influence its result of use in its inside radiating effect is poor and has in long-time operation in-process, and is inside because the poor inside mounting panel device that leads to of high temperature radiating effect is ageing, dismantles the difficulty when breaking down, and inside does not have the problem of device dust collecting equipment

Disclosure of Invention

The invention aims to provide a high-frequency high-power 3D scene modeling model making terminal to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a 3D scene modeling model of high frequency high power makes terminal, includes heat dissipation box and modeling terminal equipment body, still includes:

the heat dissipation assembly comprises a water cooling circulation component arranged on the outer side of the modeling terminal equipment body;

the water-cooling circulating component comprises a water conveying pipe which surrounds the surface of the outer side wall of the modeling terminal equipment body, and the water conveying pipe is connected with the water tank through the circulating component;

the heat dissipation assembly further comprises an air cooling component arranged at the top of the modeling terminal equipment body, the air cooling component comprises blades which are arranged in the heat dissipation box body relatively, and the blades are connected with a rotating mechanism which drives the blades to rotate.

Preferably, the circulating part comprises a piston arranged in the water tank, the top of the piston is fixedly connected with a lifting part for pushing the piston to move in the water tank, the bottom end of the water tank is connected with a water pipe, and a one-way valve only used for draining water is arranged between the water pipe and the water tank.

Preferably, the circulating part further comprises a water return pipe arranged on the other side of the heat dissipation box body, one end of the water return pipe is connected with the tail end of the water delivery pipe, the other end of the water return pipe extends to be connected with the water tank, and a check valve limited to water inlet is arranged between the water return pipe and the water tank.

Preferably, the lifting part is including arranging the sliding seal plate of bottom in the radiating box, sliding seal plate and radiating box internal side wall sliding connection, sliding seal plate bottom is through pushing away post and piston fixed connection, the relative fixed mounting guide arm in water tank both sides, the guide arm outside sets up reset spring, reset spring one end and radiating box bottom fixed connection, other end fixed connection slide, slide slidable mounting is on the guide arm surface, push away the post both ends and pass through push rod and slide fixed connection respectively, radiating box both sides wall bottom sets up the pressure release hole for the pressure release.

Preferably, sealing plates are arranged on the inner sides of the pressure relief holes on the two sides, and the sealing plates are fixedly connected with the sliding seat through connecting rods.

Preferably, the air cooling part further comprises a heat dissipation plate arranged at the top in the heat dissipation box body, multiple groups of heat dissipation grooves are uniformly arranged between the heat dissipation plates, the heat dissipation plates and the top wall of the heat dissipation box body form a heat dissipation cavity, and the blades are arranged in the heat dissipation cavity relatively.

Preferably, the heat dissipation box outside sets up driving motor, the driving motor output extends the fixed connection screw rod, the screw rod rotates and installs in the heat dissipation intracavity, screw rod both sides screw thread opposite direction, screw rod surface both sides mutual disposition nut, the nut bottom rotates connects the gear, set up the rack board in the heat dissipation intracavity, rack board and gear engagement, gear bottom and blade fixed connection.

Preferably, the driving motor is connected with a control mechanism for controlling the driving motor to open and close, the control mechanism comprises a control box, a first electrical connection sheet is arranged at the bottom in the control box, a second electrical connection sheet is arranged at the top in the control box, the second electrical connection sheet is slidably mounted in the control box, one end of the second electrical connection sheet is fixedly connected with the sleeve through a connecting rod, a buffer spring is arranged in the sleeve, one end of the buffer spring is fixedly connected with the top wall of the sleeve, the other end of the buffer spring is fixedly connected with the guide pillar, and one end of the guide pillar, far away from the sleeve, is fixedly connected with a sliding sealing plate.

Preferably, fastening screws are oppositely arranged on two sides in the heat dissipation box body, the fastening screws are in threaded connection with the side wall of the heat dissipation box body, one ends, close to each other, of the fastening screws on the two sides are rotatably connected with the L-shaped clamping plates, and the L-shaped clamping plates clamp and fix the modeling terminal device body.

Compared with the prior art, the invention has the beneficial effects that:

the modeling terminal equipment body is placed in the radiating box body, cooling water in the water tank is conveyed to a water conveying pipe surrounding the outer side of the modeling terminal equipment body through a circulating component arranged in the radiating box body, the modeling terminal equipment body is cooled through the cooling water in the water conveying pipe, meanwhile, a rotating mechanism in the radiating box body drives a blade to rotate, the blade is used for accelerating the air flow rate of the peripheral side of the modeling terminal equipment body, the heat dissipation and cooling effects of the modeling terminal equipment body are further improved, and the stable operation of the D scene modeling model manufacturing terminal equipment is guaranteed.

Drawings

Fig. 1 is a schematic structural diagram of a high-frequency high-power 3D scene modeling model making terminal.

Fig. 2 is a schematic structural diagram of a high-frequency high-power 3D scene modeling model making terminal enlarged at a in fig. 1.

Fig. 3 is a schematic structural diagram of a heat dissipation strip slot in a high-frequency high-power 3D scene modeling model manufacturing terminal.

Fig. 4 is a schematic structural diagram of a control box in a high-frequency high-power 3D scene modeling model making terminal.

In the figure: 1. a heat dissipation box body; 2. a drive motor; 3. a heat dissipation plate; 4. fastening a screw rod; 5. a sleeve; 6. a control box; 7. a guide post; 8. an L-shaped clamping plate; 9. a water delivery pipe; 10. a pressure relief vent; 11. a sealing plate; 12. a water tank; 13. a sliding seal plate; 14. a piston; 15. pushing the column; 16. a water return pipe; 17. a first electrical connection sheet; 18. modeling a terminal device body; 19. a blade; 20. a gear; 21. a rack plate; 22. a nut; 23. a screw; 24. a guide bar; 25. a slide base; 26. a push rod; 27. a return spring; 28. a heat dissipation strip groove; 29. a buffer spring; 30. and a second electrical connection pad.

Detailed Description

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only partial embodiments of the present application, but not all 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 application.

In this application, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the present application and its embodiments, and are not used to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in this application will be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "sleeved" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

Referring to fig. 1-4, a high-frequency high-power 3D scene modeling model manufacturing terminal includes a heat dissipation box 1, a modeling terminal device body 18, and a heat dissipation assembly, where the heat dissipation assembly includes a water-cooling circulation component disposed outside the modeling terminal device body 18, the water-cooling circulation component includes a water pipe 9 surrounding the outer side wall surface of the modeling terminal device body 18, the water pipe 9 is connected with a water tank 12 through a circulation component, the heat dissipation assembly further includes an air-cooling component disposed on the top of the modeling terminal device body 18, the air-cooling component includes blades 19 disposed in the heat dissipation box 1, and the blades 19 are connected with a rotation mechanism driving the blades to rotate.

Specifically, in this embodiment, the modeling terminal device body 18 is placed in the heat dissipation box body 1, the cooling water in the water tank 12 is conveyed into the water conveying pipe 9 surrounding the outside of the modeling terminal device body 18 through the circulating component arranged in the heat dissipation box body 1, the modeling terminal device body 18 is cooled through the cooling water in the water conveying pipe 9, meanwhile, the rotating mechanism arranged in the heat dissipation box body 1 drives the blades 19 to rotate, and the blades 19 are used for accelerating the air flow rate around the modeling terminal device body 18, so that the heat dissipation and cooling effects of the modeling terminal device body 18 are improved, and the stable operation of the 3D scene modeling model making terminal device is ensured.

As a further solution of the embodiment of the present invention, the circulating component includes a piston 14 disposed in the water tank 12, the top of the piston 14 is fixedly connected to a lifting component for pushing the piston to move in the water tank 12, the bottom end of the water tank 12 is connected to a water pipe 9, and a check valve limited to drainage is disposed between the water pipe 9 and the water tank 12;

specifically, in the present embodiment, the piston 14 is pushed by the lifting member to move in the water tank 12, and the piston 14 presses the water at the bottom in the water tank 12 into the water pipe 9.

As a further scheme of the embodiment of the present invention, the circulating component further includes a water return pipe 16 disposed at the other side of the heat dissipation box 1, one end of the water return pipe 16 is connected to the end of the water pipe 9, the other end of the water return pipe extends to connect the water tank 12, and a check valve limited to water inlet is disposed between the water return pipe 16 and the water tank 12;

specifically, in this embodiment, the water in the water pipe 9 flows back to the water return pipe 16 under the pushing of the piston 14, and the water return pipe 16 conveys the water to the water tank 12 in a circulating manner, so as to realize cooling water circulation, which is more energy-saving and environment-friendly.

As a further scheme of the embodiment of the invention, the lifting component includes a sliding sealing plate 13 arranged at the bottom in the heat dissipation box body 1, the sliding sealing plate 13 is connected with the inner side wall of the heat dissipation box body 1 in a sliding manner, the bottom end of the sliding sealing plate 13 is fixedly connected with a piston 14 through a push post 15, guide rods 24 are relatively and fixedly installed at two sides of the water tank 12, a return spring 27 is arranged at the outer side of each guide rod 24, one end of the return spring 27 is fixedly connected with the bottom end of the heat dissipation box body 1, the other end of the return spring is fixedly connected with a sliding seat 25, the sliding seat 25 is slidably installed on the surface of each guide rod 24, two ends of the push post 15 are respectively fixedly connected with the sliding seat 25 through a push rod 26, and pressure relief holes 10 for pressure relief are arranged at the bottoms of two side walls of the heat dissipation box body 1;

specifically, in this embodiment, the modeling terminal device body 18 generates a large amount of heat after a long-time operation process, especially in hot summer, at this time, the medium oil located above the sliding sealing plate 13 expands to increase internal pressure, the sliding sealing plate 13 is pushed to move downward under a strong pressure acting force, pressure is discharged through the pressure relief hole 10 to realize pressure relief, the sliding sealing plate 13 pushes the piston 14 to move in the water tank 12 through the push post 15, the sliding sealing plate 13 drives the sliding seats 25 on two sides to slide on the surface of the guide rod 24 through the push rod 26 in the downward movement process, the sliding seats 25 extrude the return spring 27 to contract to generate elastic force, and after the pressure relief is completed, the return spring 27 drives the sliding sealing plate 13 to reset through the elastic force.

As a further scheme of the embodiment of the invention, sealing plates 11 are arranged on the inner sides of the pressure relief holes 10 on the two sides, and the sealing plates 11 are fixedly connected with the sliding seat 25 through connecting rods;

specifically, in the embodiment, the sliding seat 25 drives the sealing plate 11 to move downwards through the connecting rod in the downward movement process, so as to be separated from the pressure relief hole 10, thereby achieving pressure relief.

As a further scheme of the embodiment of the invention, the air cooling part further comprises heat dissipation plates 3 arranged at the inner top of the heat dissipation box body 1, a plurality of groups of heat dissipation strip grooves 28 are uniformly arranged among the heat dissipation plates 3, the heat dissipation plates 3 and the top wall of the heat dissipation box body 1 form a heat dissipation cavity, and the blades 19 are oppositely arranged in the heat dissipation cavity;

specifically, in this embodiment, the rotating mechanism drives the blade 19 to rotate, and the blade 19 blows air towards the modeling terminal device body 18 through the heat dissipation strip groove 28, so as to improve the air flow efficiency.

As a further scheme of the embodiment of the invention, a driving motor 2 is arranged outside a heat dissipation box body 1, the output end of the driving motor 2 extends and is fixedly connected with a screw 23, the screw 23 is rotatably installed in a heat dissipation cavity, the thread directions of two sides of the screw 23 are opposite, nuts 22 are oppositely arranged on two sides of the surface of the screw 23, the bottom end of each nut 22 is rotatably connected with a gear 20, a rack plate 21 is arranged in the heat dissipation cavity, the rack plate 21 is meshed with the gear 20, and the bottom end of the gear 20 is fixedly connected with a blade 19;

specifically, in the present embodiment, the driving motor 2 intermittently rotates forward and backward, the nut 22 horizontally reciprocates on the surface of the screw 23, the nut 22 drives the gear 20 to reciprocate in the process of horizontal reciprocation, and the gear 20 drives the blades 19 to rotate by meshing with the rack plate 21, so that the blowing range of the blades 19 is increased, and the heat dissipation effect is better.

As a further scheme of the embodiment of the present invention, the driving motor 2 is connected to a control mechanism for controlling the on/off of the driving motor, the control mechanism includes a control box 6, a first electrical connection sheet 17 is disposed at the bottom of the control box 6, a second electrical connection sheet 30 is disposed at the top of the control box 6, the second electrical connection sheet 30 is slidably mounted in the control box 6, one end of the second electrical connection sheet 30 is fixedly connected to the sleeve 5 through a connection rod, a buffer spring 29 is disposed in the sleeve 5, one end of the buffer spring 29 is fixedly connected to the top wall of the sleeve 5, the other end of the buffer spring is fixedly connected to the guide pillar 7, and one end of the guide pillar 7, which is far away from the sleeve 5, is fixedly connected to the sliding sealing plate 13;

specifically, in this embodiment, the sliding sealing plate 13 drives the second electrical connection sheet 30 to move towards the first electrical connection sheet 17 through the guide pillar 7 and the sleeve 5 in the downward moving process, and the two electrical connection sheets are electrically connected in contact with each other, so as to start the driving motor 2, thereby realizing the synchronous operation of the air cooling part and the water cooling part, and achieving a better heat dissipation effect.

As a further scheme of the embodiment of the invention, fastening screws 4 are oppositely arranged on two sides in the heat dissipation box body 1, the fastening screws 4 are in threaded connection with the side wall of the heat dissipation box body 1, one ends of the fastening screws 4 on the two sides, which are close to each other, are rotatably connected with an L-shaped clamping plate 8, and the L-shaped clamping plate 8 clamps and fixes the modeling terminal device body 18.

The working principle of the invention is as follows: placing a modeling terminal device body 18 in the heat dissipation box body 1, wherein the modeling terminal device body 18 generates a large amount of heat after a long-time operation process, especially in hot summer, at the moment, medium oil above the sliding sealing plate 13 expands to increase internal pressure, the sliding sealing plate 13 is pushed to move downwards under strong pressure acting force, pressure is discharged through the pressure relief hole 10 to realize pressure relief, the sliding sealing plate 13 pushes the piston 14 to move in the water tank 12 through the push column 15, the sliding sealing plate 13 drives the sliding seats 25 at two sides to slide on the surface of the guide rod 24 through the push rod 26 in the downward movement process, the sliding seats 25 extrude the return spring 27 to contract to generate elastic force, after pressure relief is completed, the return spring 27 drives the sliding sealing plate 13 to return through the elastic force, and conveys cooling water in the water tank 12 to the water conveying pipe 9 around the outer side of the modeling terminal device body 18, the modeling terminal device body 18 is cooled by cooling water in the water delivery pipe 9, meanwhile, the driving motor 2 intermittently rotates forwards and backwards, the nut 22 horizontally reciprocates on the surface of the screw rod 23, the nut 22 drives the gear 20 to reciprocate in the horizontal reciprocating process, the gear 20 drives the blade 19 to rotate by meshing with the rack plate 21, the blade 19 is used for accelerating the air flow rate on the peripheral side of the modeling terminal device body 18, the sliding sealing plate 13 drives the second electric connecting plate 30 to move towards the first electric connecting plate 17 through the guide pillar 7 and the sleeve 5 in the downward moving process, the two electric connecting plates are in contact power-on, the driving motor 2 is started, and synchronous operation of air cooling and water cooling parts is realized.

While the preferred embodiments of the present invention have been described in detail, the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art.

Claims (9)

1. The utility model provides a 3D scene modeling model of high frequency high power makes terminal, includes heat dissipation box (1) and modeling terminal equipment body (18), its characterized in that still includes:

a heat dissipation assembly including a water-cooling circulation part disposed outside the modeling terminal device body (18);

the water-cooling circulating component comprises a water conveying pipe (9) surrounding the surface of the outer side wall of the modeling terminal equipment body (18), and the water conveying pipe (9) is connected with the water tank (12) through the circulating component;

the heat dissipation assembly further comprises an air cooling component arranged at the top of the modeling terminal device body (18), the air cooling component comprises blades (19) which are arranged in the heat dissipation box body (1) relatively, and the blades (19) are connected with a rotating mechanism which drives the blades to rotate.

2. The terminal for modeling the 3D scene with high frequency and high power according to claim 1, wherein the circulating component comprises a piston (14) disposed in the water tank (12), the top of the piston (14) is fixedly connected with a lifting component for pushing the piston to move in the water tank (12), the bottom of the water tank (12) is connected with a water pipe (9), and a one-way valve limited to drainage is disposed between the water pipe (9) and the water tank (12).

3. The terminal for modeling the 3D scene with high frequency and high power according to claim 1 or 2, wherein the circulating component further comprises a water return pipe (16) disposed at the other side of the heat dissipation box (1), one end of the water return pipe (16) is connected with the end of the water pipe (9), the other end of the water return pipe extends to be connected with the water tank (12), and a check valve limited to water inlet is disposed between the water return pipe (16) and the water tank (12).

4. The terminal for manufacturing the high-frequency high-power 3D scene modeling model according to claim 3, wherein the lifting component comprises a sliding sealing plate (13) arranged at the bottom inside the heat dissipation box body (1), the sliding sealing plate (13) is connected with the inner side wall of the heat dissipation box body (1) in a sliding manner, the bottom end of the sliding sealing plate (13) is fixedly connected with a piston (14) through a push rod (15), guide rods (24) are relatively and fixedly installed at two sides of the water tank (12), a return spring (27) is arranged at the outer side of each guide rod (24), one end of each return spring (27) is fixedly connected with the bottom end of the heat dissipation box body (1), the other end of each return spring is fixedly connected with a sliding seat (25), the sliding seats (25) are slidably installed on the surfaces of the guide rods (24), two ends of each push rod (15) are fixedly connected with the sliding seats (25) through push rods (26), two side walls at the bottom of the heat dissipation box body (1) are provided with pressure relief holes (10), for pressure relief.

5. The high-frequency high-power 3D scene modeling terminal according to claim 4, wherein sealing plates (11) are arranged on the inner sides of the pressure relief holes (10), and the sealing plates (11) are fixedly connected with the sliding base (25) through connecting rods.

6. The terminal for manufacturing the high-frequency high-power 3D scene modeling model according to claim 5, wherein the air cooling component further comprises a heat dissipation plate (3) arranged at the inner top of the heat dissipation box body (1), a plurality of groups of heat dissipation strip grooves (28) are uniformly arranged among the heat dissipation plate (3), the heat dissipation plate (3) and the top wall of the heat dissipation box body (1) form a heat dissipation cavity, and the blades (19) are oppositely arranged in the heat dissipation cavity.

7. The terminal for manufacturing the high-frequency high-power 3D scene modeling model according to claim 6, wherein a driving motor (2) is arranged outside the heat dissipation box body (1), the output end of the driving motor (2) extends to be fixedly connected with a screw rod (23), the screw rod (23) is rotatably installed in the heat dissipation cavity, the thread directions of two sides of the screw rod (23) are opposite, nuts (22) are oppositely arranged on two sides of the surface of the screw rod (23), the bottom end of each nut (22) is rotatably connected with a gear (20), a rack plate (21) is arranged in the heat dissipation cavity, the rack plate (21) is meshed with the gear (20), and the bottom end of the gear (20) is fixedly connected with the blade (19).

8. A high frequency high power 3D scene modeling terminal according to claim 7, it is characterized in that the driving motor (2) is connected with a control mechanism for controlling the opening and closing of the driving motor, the control mechanism comprises a control box (6), a first electric connecting sheet (17) is arranged at the bottom in the control box (6), a second electric connecting sheet (30) is arranged at the top, the second electrical connection sheet (30) is arranged in the control box (6) in a sliding way, one end of the second electrical connection sheet (30) is fixedly connected with the sleeve (5) through a connecting rod, a buffer spring (29) is arranged in the sleeve (5), one end of the buffer spring (29) is fixedly connected with the top wall of the sleeve (5), the other end is fixedly connected with the guide post (7), one end of the guide post (7) far away from the sleeve (5) is fixedly connected with the sliding sealing plate (13).

9. The terminal for manufacturing the high-frequency high-power 3D scene modeling model according to claim 8, wherein fastening screws (4) are oppositely arranged on two sides in the heat dissipation box body (1), the fastening screws (4) are in threaded connection with the side wall of the heat dissipation box body (1), one ends, close to each other, of the fastening screws (4) on the two sides are rotatably connected with L-shaped clamping plates (8), and the L-shaped clamping plates (8) clamp and fix the modeling terminal device body (18).

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