阅读说明：本技术 增材制造局部均匀散热在线处理结构 (Online processing structure for locally and uniformly radiating in additive manufacturing ) 是由 张志平 于 2020-11-17 设计创作，主要内容包括：本发明公开了增材制造局部均匀散热在线处理结构,包括圆座、移动组件和调节组件；圆座：底部设有供水组件；移动组件：包括圆形滑轨、弧形滑块、第一电机、齿轮、齿圈、支板和底座,圆形滑轨固定套接在圆座的圆周侧面上,弧形滑块滑动连接在圆形滑轨内,第一电机固定连接在弧形滑块的表面,齿轮固定套接在第一电机的输出轴上,齿圈固定套接在圆座的圆周侧面的顶部,且齿圈与齿轮啮合,支板对称设有两个且分别设于弧形滑块的表面两侧,本增材制造局部均匀散热在线处理结构可实现增材制造产品的局部均匀散热,降低对机械性能的影响,提高产品的合格率,减少了原料的浪费,使产品可以更好的满足使用要求,实用性较强。(The invention discloses an additive manufacturing local uniform heat dissipation online processing structure, which comprises a round seat, a moving assembly and an adjusting assembly, wherein the round seat is arranged on the round seat; a round seat: the bottom is provided with a water supply component; a moving component: including circular slide rail, the arc slider, first motor, the gear, the ring gear, extension board and base, the fixed cover of circular slide rail is cup jointed on the circumference side of circle seat, arc slider sliding connection is in circular slide rail, first motor fixed connection is on the surface of arc slider, the fixed cover of gear is on the output shaft of first motor, the fixed top of cup jointing the circumference side of circle seat of ring gear, and ring gear and gear engagement, the extension board symmetry is equipped with two and locates the surperficial both sides of arc slider respectively, this local even heat dissipation on-line processing structure of additive manufacturing can realize the local even heat dissipation of additive manufacturing product, reduce the influence to mechanical properties, improve the qualification rate of product, the waste of raw materials has been reduced, make satisfying operation requirement that the product can be better, the practicality is stronger.)

1. Local even heat dissipation of vibration material disk handles structure on line, its characterized in that: comprises a round seat (1), a moving component (2) and an adjusting component (3);

round base (1): the bottom is provided with a water supply component (5);

moving assembly (2): the sliding device comprises a circular sliding rail (21), an arc-shaped sliding block (22), a first motor (23), a gear (24), a gear ring (25), a support plate (26) and a base (27), wherein the circular sliding rail (21) is fixedly sleeved on the circumferential side face of a circular seat (1), the arc-shaped sliding block (22) is connected in the circular sliding rail (21) in a sliding manner, the first motor (23) is fixedly connected to the surface of the arc-shaped sliding block (22), the gear (24) is fixedly sleeved on an output shaft of the first motor (23), the gear ring (25) is fixedly sleeved on the top of the circumferential side face of the circular seat (1), the gear ring (25) is meshed with the gear (24), the two support plates (26) are symmetrically arranged and are respectively arranged on two sides of the surface of the arc-shaped sliding block (22), and the base (27) is fixedly connected to the top of the;

adjusting assembly (3): comprises a vertical rail (31), a screw rod (32), a sliding block (33), a rack (34), a second motor (35), a mounting groove (36), a third motor (37), a bracket (38), a screw rod (39) and a thread cylinder (391), wherein the bottom of the vertical rail (31) is fixedly connected on the surface of a base (27), the screw rod (32) is rotatably connected in the vertical rail (31), the sliding block (33) is in threaded connection with the screw rod (32) through a threaded hole in the middle part, the side surface of the sliding block (33) is in sliding connection with the inner side surface of the vertical rail (31), the rack (34) is fixedly connected on the top surface of the vertical rail (31), the second motor (35) is fixedly connected on the rack (34), the output shaft of the second motor (35) is fixedly connected with the top end of the screw rod (32), the mounting groove (36) is arranged on the side surface of the sliding block (33), and the third motor (37) is fixedly connected in the mounting groove (, the support (38) is fixedly connected to the side face of the sliding block (33), the support (38) corresponds to the mounting groove (36), one end of the screw rod (39) is rotatably connected to the support (38), one end of the screw rod (39) is fixedly connected with an output shaft of the third motor (37), the threaded cylinder (391) is connected to the screw rod (39) through a screw hole in the middle in a threaded manner, the threaded cylinder (391) is provided with the water cooling assembly (4), the water cooling assembly (4) is provided with the air cooling assembly (7), and the vertical rail (31) is provided with the auxiliary assembly (6);

wherein: still include PLC controller (11), PLC controller (11) fixed connection is on the surface of circle seat (1), and the input of PLC controller (11) is connected with external power source's output electricity, and the output of PLC controller (11) is connected with the input electricity of first motor (23) and second motor (35) respectively.

2. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 1, wherein: water-cooling subassembly (4) include mount pad (41), branch pipe (42), cylinder (43) and hose (44), mount pad (41) fixed connection is in the one end of threaded sleeve (391), branch pipe (42) symmetry is equipped with two and runs through the both sides of mount pad (41) respectively, the both ends of cylinder (43) are rotated respectively and are connected in the relative one end of both sides branch pipe (42), hose (44) symmetry is equipped with two, and the one end of two hoses (44) is connected with the one end of keeping away from each other respectively on branch pipe (42) of both sides.

3. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 2, wherein: water-cooling subassembly (4) still include fixing base (45), fixed block (46), cooling cylinder (47), semiconductor refrigeration piece (48) and connecting pipe (49), the side of erecting rail (31) is located in fixing base (45), the side of fixing base (45) is located in fixed block (46), cooling cylinder (47) are located on fixed block (46), and the top surface of cooling cylinder (47) and hose (44) intercommunication of one side wherein, semiconductor refrigeration piece (48) are located on the circumference side of cooling cylinder (47), and the cold junction of semiconductor refrigeration piece (48) and the side laminating of cooling cylinder (47), the bottom surface of cooling cylinder (47) is located in connecting pipe (49), and the input of semiconductor refrigeration piece (48) is connected with the output electricity of PLC controller (11).

4. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 3, wherein: water supply unit (5) are including circular slot (51), inlet tube (52), curb plate (53) and self priming pump (54), the bottom surface of circle seat (1) is located in circular slot (51), the circumference side upper portion of circular slot (51) is located in inlet tube (52), and the one end of inlet tube (52) is connected with connecting pipe (49), the side of circular slot (51) is located in curb plate (53), the surface of curb plate (53) is located in self priming pump (54), and the input of self priming pump (54) is connected with the output electricity of PLC controller (11).

5. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 4, wherein: the water supply assembly (5) still includes and absorbs water tub (55) and drain pipe (56), the one end that absorbs water tub (55) is connected with the port of intaking of self priming pump (54), and the other end that absorbs water tub (55) passes the inside that the side of circular slot (51) extended to circular slot (51), the play water port of self priming pump (54) is located to the one end of drain pipe (56), and the other end and the hose (44) of opposite side of drain pipe (56) are connected.

6. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 3, wherein: auxiliary assembly (6) are including fixed plate (61), frame plate (62), prop up piece (63) and restraint ring (64), the side of erecting rail (31) is located to fixed plate (61), the one end of frame plate (62) is located on fixed plate (61), prop up the side of frame plate (62) in piece (63), restraint ring (64) activity is cup jointed on hose (44), and the one end fixed connection who restraints ring (64) and prop up piece (63).

7. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 1, wherein: air-cooled subassembly (7) include riser (71), temperature sensor (72), collar (73), dead lever (74) and fan (75), the surface of mount pad (41) is located in riser (71), the side of riser (71) is located in temperature sensor (72), the top of riser (71) is located in collar (73), the inboard of collar (73) is located in dead lever (74), on dead lever (74) is located in fan (75), the input of fan (75) is connected with the output electricity of PLC controller (11).

8. The additive-fabricated locally-uniform heat-dissipation in-line processing structure of claim 7, wherein: the air cooling assembly (7) further comprises a fixing ring (76) and heat conducting fins (77), the fixing ring (76) is arranged on the back side of the mounting ring (73), and the heat conducting fins (77) are uniformly arranged on the side face of the fixing ring (76) and are perpendicular to the mounting ring (73).

9. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 1, wherein: still include support (8), infrared thermal imager (81) and display screen (82), the surface of frame (34) is located in support (8), infrared thermal imager (81) is located on support (8), display screen (82) are located on support (8), and the input of infrared thermal imager (81) is connected with the output electricity of PLC controller (11), and the output of infrared thermal imager (81) is connected with the input electricity of display screen (82).

10. The additive manufactured locally uniform heat dissipation in-line processing structure of claim 1, wherein: the thread sleeve is characterized by further comprising a limiting block (9) and a guide rod (91), wherein the limiting block (9) is arranged on the side face of the thread sleeve (391), one end of the guide rod (91) is arranged on the side face of the support (38), and the other end of the guide rod (91) penetrates through the limiting block (9).

Technical Field

The invention relates to the technical field of additive manufacturing, in particular to an additive manufacturing local uniform heat dissipation online processing structure.

Background

Additive manufacturing is commonly known as 3D printing, computer aided design, material processing and forming technologies are fused, a digital model file is used as a base, special metal materials, non-metal materials and medical biological materials are stacked layer by layer through software and a numerical control system according to modes of extrusion, sintering, melting, photocuring, spraying and the like, and a manufacturing technology for manufacturing solid objects is a manufacturing method through material accumulation from bottom to top compared with the traditional processing mode of removing, cutting and assembling raw materials, the manufacturing method needs to dissipate heat after the solid is manufactured through additive manufacturing, local uneven heat dissipation is caused due to different thicknesses and shapes of parts of the solid, the mechanical performance of the solid is influenced, the existing partial heat dissipation mode cannot realize local even heat dissipation of the solid, and the use requirements of products manufactured through additive manufacturing are not met, causing waste of raw materials and energy and inconvenient use.

Disclosure of Invention

The technical problem to be solved by the invention is to overcome the existing defects, provide an additive manufacturing local uniform heat dissipation online processing structure, realize local uniform heat dissipation of an additive manufacturing product, reduce the influence on mechanical performance, improve the qualification rate of the product, reduce the waste of raw materials, enable the product to better meet the use requirement, have strong practicability and effectively solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the material increase manufacturing local uniform heat dissipation online processing structure comprises a round seat, a moving assembly and an adjusting assembly;

a round seat: the bottom is provided with a water supply component;

a moving component: the sliding mechanism comprises a circular sliding rail, an arc-shaped sliding block, a first motor, gears, a gear ring, support plates and a base, wherein the circular sliding rail is fixedly sleeved on the circumferential side surface of a circular seat, the arc-shaped sliding block is connected in the circular sliding rail in a sliding manner, the first motor is fixedly connected to the surface of the arc-shaped sliding block, the gears are fixedly sleeved on an output shaft of the first motor, the gear ring is fixedly sleeved on the top of the circumferential side surface of the circular seat, the gear ring is meshed with the gears, the two support plates are symmetrically arranged and are respectively arranged on two sides of the surface of the arc-shaped sliding block, and the base;

the adjusting component: the screw rod fixing device comprises a vertical rail, a screw rod, a sliding block, a rack, a second motor, a mounting groove, a third motor, a support, a screw rod and a threaded cylinder, wherein the bottom of the vertical rail is fixedly connected to the surface of a base, the screw rod is rotatably connected into the vertical rail, the sliding block is in threaded connection with the screw rod through a threaded hole in the middle, the side surface of the sliding block is in sliding connection with the inner side surface of the vertical rail, the rack is fixedly connected to the top surface of the vertical rail, the second motor is fixedly connected to the rack, an output shaft of the second motor is fixedly connected with the top end of the screw rod, the mounting groove is formed in the side surface of the sliding block, the third motor is fixedly connected into the mounting groove, the support is fixedly connected to the side surface of the sliding block, the support corresponds to the mounting groove, one end of the screw rod is rotatably connected to the support, a water cooling assembly is arranged on the threaded cylinder, an air cooling assembly is arranged on the water cooling assembly, and an auxiliary assembly is arranged on the vertical rail;

wherein: still include the PLC controller, PLC controller fixed connection is on the surface of circle seat, and the input of PLC controller is connected with external power source's output electricity, and the output of PLC controller is connected with the input electricity of first motor and second motor respectively.

Further, the water cooling subassembly includes mount pad, branch pipe, cylinder and hose, mount pad fixed connection is in the one end of a screw thread section of thick bamboo, the branch pipe symmetry is equipped with two and runs through the both sides of mount pad respectively, the both ends of cylinder rotate the relative one end of connection in both sides branch pipe respectively, the hose symmetry is equipped with two, and the one end of two hoses is connected with the one end of keeping away from each other respectively on the branch pipe of both sides.

Further, the water-cooling assembly further comprises a fixing seat, a fixing block, a cooling cylinder, a semiconductor refrigeration piece and a connecting pipe, wherein the fixing seat is arranged on the side face of the vertical rail, the fixing block is arranged on the side face of the fixing seat, the cooling cylinder is arranged on the fixing block, the top face of the cooling cylinder is communicated with the hose on one side, the semiconductor refrigeration piece is arranged on the circumferential side face of the cooling cylinder, the cold end of the semiconductor refrigeration piece is attached to the side face of the cooling cylinder, the connecting pipe is arranged on the bottom face of the cooling cylinder, the input end of the semiconductor refrigeration piece is electrically connected with the output end of the PLC, the water-cooling assembly can utilize the water supply assembly, water enters the drum from the hose on one side, enters the drum through a branch pipe, cools the drum, heat exchange with the entity is realized by the drum, the entity dissipates heat and cools down, then the water is discharged from, and finally, the water flows back into the circular groove through the water inlet pipe to be used again.

Further, the water supply subassembly includes circular slot, inlet tube, curb plate and self priming pump, the bottom surface of circle seat is located to the circular slot, the circumference side upper portion of circular slot is located to the inlet tube, and the one end and the connecting pipe of inlet tube are connected, the side of circular slot is located to the curb plate, the surface of curb plate is located to the self priming pump, and the input of self priming pump is connected with the output electricity of PLC controller.

Further, water supply assembly still includes the pipe and the drain pipe that absorb water, the one end that absorbs water the pipe is connected with the port of intaking of self priming pump, and the other end that absorbs water the pipe passes the side of circular slot and extends to the inside of circular slot, the play water port of self priming pump is located to the one end of drain pipe, and the other end of drain pipe and the hose connection of opposite side, and the usable self priming pump of water supply assembly takes water out from the circular slot through the pipe that absorbs water, in the drain pipe gets into the hose, can realize the circulation flow of water.

Further, the auxiliary assembly comprises a fixed plate, a frame plate, a supporting block and a binding ring, the fixed plate is arranged on the side face of the vertical rail, one end of the frame plate is arranged on the fixed plate, the supporting block is arranged on the side face of the frame plate, the binding ring is movably sleeved on the hose, the binding ring is fixedly connected with one end of the supporting block, the auxiliary assembly can be supported by the binding ring in a limited mode, and the hose is prevented from being scattered and bent.

Further, the forced air cooling subassembly includes riser, temperature sensor, collar, dead lever and fan, the surface of mount pad is located to the riser, temperature sensor locates the side of riser, the top of riser is located to the collar, the inboard of collar is located to the dead lever, on the dead lever was located to the fan, the input of fan was connected with the output electricity of PLC controller.

Further, the air-cooled subassembly still includes retainer plate and conducting strip, the dorsal part of collar is located to the retainer plate, the side of retainer plate and perpendicular with the collar are evenly located to the conducting strip, and the air-cooled subassembly can be when the water-cooled subassembly meets the place that can't contact, and usable fan cools down the heat dissipation to the part of entity, and the conducting strip can be to the inspiratory air cooling of fan, improves the radiating efficiency of fan, and temperature sensor can monitor the temperature of entity, when monitoring the difference in temperature between the entity part too big, can judge out the local heat dissipation inequality of entity.

Further, still include support, infrared thermal imager and display screen, the surface of frame is located to the support, infrared thermal imager locates on the support, the display screen is located on the support, and infrared thermal imager's input is connected with the output electricity of PLC controller, and infrared thermal imager's output is connected with the input electricity of display screen, and infrared thermal imager can present the temperature image in each region on the entity on the display screen, makes the temperature in each region of entity more audio-visual showing.

Furthermore, the screw thread device further comprises a limiting block and a guide rod, the limiting block is arranged on the side face of the screw thread cylinder, one end of the guide rod is arranged on the side face of the support, the other end of the guide rod penetrates through the limiting block, the limiting block and the guide rod can limit the screw thread cylinder, and the rotation of the screw thread cylinder is avoided.

Compared with the prior art, the invention has the beneficial effects that: this local even heat dissipation of vibration material disk handles structure on line has following benefit:

1. this usable water supply assembly of water-cooling subassembly of local even heat dissipation on-line processing structure of vibration material disk, water gets into from the hose of one of them side, gets into the cylinder through the branch pipe in, cools down the cylinder, utilizes the cylinder to realize with the heat exchange of entity, dispels the heat for the entity and cools down, then in water gets into the cooling cylinder from the hose discharge of opposite side, utilizes semiconductor refrigeration piece to make water recooling again, at last through the inlet tube reflux round inslot reuse.

2. This air-cooled subassembly of local even heat dissipation on-line processing structure of vibration material disk can meet the place that can't contact at water-cooled subassembly, and usable fan cools down the heat dissipation to the local of entity, and the conducting strip can be to the inspiratory air cooling of fan, improves the radiating efficiency of fan, and temperature sensor can monitor the temperature of entity, when monitoring the local difference in temperature between the entity too big, can judge that the local heat dissipation of entity is uneven.

3. The infrared thermal imager with the additive manufacturing local uniform heat dissipation online processing structure can display temperature images of all areas on an entity on a display screen, so that the temperature of all areas of the entity can be displayed more visually.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged schematic view of the structure at the position A of the present invention;

FIG. 3 is a schematic side view of the present invention;

FIG. 4 is a schematic side view of the present invention.

In the figure: 1 round seat, 11PLC controller, 2 moving assembly, 21 circular slide rail, 22 arc slide block, 23 first motor, 24 gear, 25 gear ring, 26 support plate, 27 base, 3 adjusting assembly, 31 vertical rail, 32 screw rod, 33 slide block, 34 frame, 35 second motor, 36 mounting groove, 37 third motor, 38 support, 39 screw rod, 391 threaded cylinder, 4 water cooling assembly, 41 mounting seat, 42 branch pipe, 43 roller, 44 hose, 45 fixing seat, 46 fixing block, 47 cooling cylinder, 48 semiconductor refrigerating sheet, 49 connecting pipe, 5 water supply assembly, 51 round groove, 52 water inlet pipe, 53 side plate, 54 self-priming pump, 55 water suction pipe, 56 water discharge pipe, 6 auxiliary assembly, 61 fixing plate, 62 frame plate, 63 support block, 64 beam ring, 7 air cooling assembly, 71 vertical plate, 72 temperature sensor, 73 mounting ring, fixing rod 74, 75 fan, 76 fixing ring, 77 heat conducting sheet, 8 support, 81 infrared thermal imaging instrument, 82 display screens, 9 limiting blocks and 91 guide rods.

Detailed Description

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.

Referring to fig. 1-4, the present invention provides a technical solution: the material increase manufacturing local uniform heat dissipation online processing structure comprises a round seat 1, a moving assembly 2 and an adjusting assembly 3;

1, round seat 1: the bottom is equipped with water supply unit 5, water supply unit 5 includes circular slot 51, inlet tube 52, curb plate 53 and self priming pump 54, the bottom surface of circular seat 1 is located to circular slot 51, inlet tube 52 locates circular slot 51's circumference side upper portion, and the one end and the connecting pipe 49 of inlet tube 52 are connected, the side of circular slot 51 is located to curb plate 53, self priming pump 54 locates the surface of curb plate 53, the input of self priming pump 54 is connected with PLC controller 11's output electricity, still include suction tube 55 and drain pipe 56, the one end of suction tube 55 is connected with the inlet port of self priming pump 54, and the other end of suction tube 55 passes the side of circular slot 51 and extends to the inside of circular slot 51, the outlet port of self priming pump 54 is located to the one end of drain pipe 56, and the other end of drain pipe 56 is connected with the hose;

the moving assembly 2: the device comprises a circular slide rail 21, an arc-shaped sliding block 22, a first motor 23, a gear 24, a gear ring 25, support plates 26 and a base 27, wherein the circular slide rail 21 is fixedly sleeved on the circumferential side surface of a circular seat 1, the arc-shaped sliding block 22 is slidably connected in the circular slide rail 21, the first motor 23 is fixedly connected to the surface of the arc-shaped sliding block 22, the gear 24 is fixedly sleeved on an output shaft of the first motor 23, the gear ring 25 is fixedly sleeved on the top of the circumferential side surface of the circular seat 1, the gear ring 25 is meshed with the gear 24, the two support plates 26 are symmetrically arranged and are respectively arranged on two sides of the surface of the arc-shaped sliding block 22;

the adjusting component 3: comprises a vertical rail 31, a screw rod 32, a sliding block 33, a rack 34, a second motor 35, a mounting groove 36, a third motor 37, a support 38, a screw rod 39 and a thread cylinder 391, wherein the bottom of the vertical rail 31 is fixedly connected on the surface of a base 27, the screw rod 32 is rotatably connected in the vertical rail 31, the sliding block 33 is in threaded connection with the screw rod 32 through a threaded hole in the middle part, the side surface of the sliding block 33 is in sliding connection with the inner side surface of the vertical rail 31, the rack 34 is fixedly connected on the top surface of the vertical rail 31, the second motor 35 is fixedly connected on the rack 34, the output shaft of the second motor 35 is fixedly connected with the top end of the screw rod 32, the mounting groove 36 is arranged on the side surface of the sliding block 33, the third motor 37 is fixedly connected in the mounting groove 36, the support 38 is fixedly connected on the side surface of the sliding block 33, the support 38 corresponds to the mounting groove 36, one, the threaded barrel 391 is in threaded connection with the screw rod 39 through a screw hole in the middle, the threaded barrel 391 is provided with a water cooling assembly 4, the water cooling assembly 4 comprises a mounting seat 41, a branch pipe 42, a roller 43 and a hose 44, the mounting seat 41 is fixedly connected with one end of the threaded barrel 391, the branch pipe 42 is symmetrically provided with two parts and respectively penetrates through two sides of the mounting seat 41, two ends of the roller 43 are respectively and rotatably connected with opposite ends of the branch pipes 42 on two sides, the hose 44 is symmetrically provided with two parts, one end of each of the two hoses 44 is respectively connected with one end, far away from each other, of the branch pipe 42 on two sides, the water cooling assembly further comprises a fixed seat 45, a fixed block 46, a cooling barrel 47, a semiconductor refrigeration sheet 48 and a connecting pipe 49, the fixed seat 45 is arranged on the side surface of the vertical rail 31, the fixed block 46 is arranged on the side surface of the fixed seat 45, the cooling, the cold end of the semiconductor refrigeration sheet 48 is attached to the side surface of the cooling cylinder 47, the connecting pipe 49 is arranged on the bottom surface of the cooling cylinder 47, the input end of the semiconductor refrigeration sheet 48 is electrically connected with the output end of the PLC 11, the water cooling component 4 is provided with the air cooling component 7, the air cooling component 7 comprises a vertical plate 71, a temperature sensor 72, a mounting ring 73, a fixing rod 74 and a fan 75, the vertical plate 71 is arranged on the surface of the mounting seat 41, the temperature sensor 72 is arranged on the side surface of the vertical plate 71, the mounting ring 73 is arranged at the top of the vertical plate 71, the fixing rod 74 is arranged on the inner side of the mounting ring 73, the fan 75 is arranged on the fixing rod 74, the input end of the fan 75 is electrically connected with the output end of the PLC 11, the cooling device further comprises a fixing ring 76 and a heat conducting sheet 77, the fixing ring 76 is arranged on the back side, the auxiliary assembly 6 comprises a fixed plate 61, a frame plate 62, a support block 63 and a binding ring 64, wherein the fixed plate 61 is arranged on the side surface of the vertical rail 31, one end of the frame plate 62 is arranged on the fixed plate 61, the support block 63 is arranged on the side surface of the frame plate 62, the binding ring 64 is movably sleeved on the hose 44, and the binding ring 64 is fixedly connected with one end of the support block 63;

wherein: still include PLC controller 11, PLC controller 11 fixed connection is on the surface of round seat 1, and PLC controller 11's input is connected with external power source's output electricity, and PLC controller 11's output is connected with the input electricity of first motor 23 and second motor 35 respectively.

Wherein: the device is characterized by further comprising a support 8, an infrared thermal imager 81 and a display screen 82, wherein the support 8 is arranged on the surface of the rack 34, the infrared thermal imager 81 is arranged on the support 8, the display screen 82 is arranged on the support 8, the input end of the infrared thermal imager 81 is electrically connected with the output end of the PLC 11, and the output end of the infrared thermal imager 81 is electrically connected with the input end of the display screen 82; the thread sleeve is characterized by further comprising a limiting block 9 and a guide rod 91, wherein the limiting block 9 is arranged on the side face of the thread sleeve 391, one end of the guide rod 91 is arranged on the side face of the support 38, and the other end of the guide rod 91 penetrates through the limiting block 9.

The water cooling module 4 can enter the roller 43 through the branch pipe 42 after water enters from the hose 44 on one side, cool the roller 43, utilize the contact of the roller 43 and the entity, and utilize the second motor 35 to roll up and down, realize the heat exchange with the entity, cool down for the entity dispels the heat.

When in use:

firstly, the gear 24 is driven to rotate by the rotation of the first motor 23, the gear 24 can realize the sliding of the arc-shaped sliding block 22 along the circular sliding rail 21 through the meshing with the gear ring 25, and further the solid rotation around the material increase manufacturing on the circular base 1 can be realized, the local heat dissipation of the solid can be realized by 360 degrees, secondly, the screw rod 32 is driven to rotate by the rotation of the second motor 35, the lifting of the sliding block 33 can be realized under the action of the vertical rail 31, meanwhile, the screw rod 39 can be driven to rotate by the rotation of the third motor 37, the linear movement of the thread cylinder 391 can be realized under the action of the limiting block 9 and the guide rod 91, the position adjustment of the water cooling component 4 and the air cooling component 7 can be realized, the temperature of the solid can be monitored by the temperature sensor 72, when the temperature difference between the local parts of the solid is monitored, the local heat dissipation unevenness of the solid can be judged, then, the water is pumped out of the circular groove 51 through the, water enters from the hose 44 on one side of the water cooling assembly, enters the roller 43 through the branch pipe 42, the roller 43 is cooled, the roller 43 is contacted with an entity, the second motor 35 is used for rolling up and down, heat exchange with the entity is realized, heat dissipation and cooling are carried out on the entity, then the water is discharged from the hose 44 on the other side and enters the cooling cylinder 47, the water is cooled again through the semiconductor refrigerating sheet 48, and finally flows back to the circular groove 51 through the water inlet pipe 52 for reuse, when the water cooling assembly 4 meets a place which cannot be contacted, the fan 75 can be used for cooling and radiating the local part of the entity, the heat conducting sheet 77 can cool air sucked by the fan 75, the heat dissipation efficiency of the fan 75 on the entity is improved, the infrared thermal imager 81 can present temperature images of all areas on the entity on the display screen 82, and the temperature of all areas of the entity can be more visually presented.

It should be noted that the specific model of the core chip of the PLC controller disclosed in this embodiment is siemens S7-400, and the first motor 23, the second motor 35, the third motor 37, the semiconductor cooling plate 48, the self-priming pump 54, the temperature sensor 72, the fan 75, the infrared thermal imager 81, and the display screen 82 may be freely configured according to an actual application scenario. The PLC controller controls the first motor 23, the second motor 35, the third motor 37, the semiconductor refrigerating sheet 48, the self-priming pump 54, the temperature sensor 72, the fan 75, the infrared thermal imager 81 and the display screen 82 to work by a method commonly used in the prior art.

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