CN114735398B - Concentrated material collecting system for radiating fins - Google Patents

Abstract

The invention relates to the technical field of conveying systems, in particular to a concentrated material collecting system for cooling fins. The invention provides a concentrated material collecting system for radiating fins, which comprises the following components: the conveying part is arranged at the upper end of the supporting frame and is suitable for conveying workpieces; the lifting part is fixed at one end of the supporting frame, the lifting part is matched with the conveying part, and a detection device is fixed at the upper end of the lifting part; the cooling part is rectangular, the inside of the cooling part is hollow, the cooling part is suitable for cooling a workpiece, and the cooling part is suitable for cooling the workpiece when the workpiece is placed in the cooling part; the conveying part is suitable for conveying the cooling part placed at the upper end of the conveying part to the lifting part; the lifting part lifts the cooling part upwards to detect whether the cooling of the workpiece in the cooling part is qualified. Through the cooperation of conveying portion and elevating gear, make full use of the space on conveyer belt upper portion, the cooling portion carries out the cooling work to the work piece simultaneously, compares traditional conveyer belt cooling, has saved equipment occupation of land space.

Description

Concentrated material collecting system for radiating fins

Technical Field

The invention relates to the technical field of conveying systems, in particular to a concentrated material collecting system for cooling fins.

Background

The conveyer belt, belt conveyor are extensively used for carrying various solid cubic and powder form material or finished goods article in agriculture, industrial and mining enterprise and transportation industry, and the conveyer belt can serialization, high efficiency, the transportation of big inclination, and conveyer belt operation is safe, and the conveyer belt is simple and convenient to use, and easy maintenance, the freight is cheap to can shorten the transportation distance, reduce engineering cost, use manpower sparingly and materials.

In the processing process of the workpiece, a large amount of heat can be generated, so that the workpiece is required to be radiated, and meanwhile, whether the workpiece is required to be radiated reaches the standard or not is detected, the temperature of the workpiece is required to be measured, and the floor area of a conveying belt is reduced, the temperature is often reduced and the temperature is often set up upwards, the workpiece is required to be lifted upwards, but in the lifting process, the workpiece is required to be prevented from sliding off in the conveying process and the lifting process, meanwhile, in order to improve the working efficiency, the conveying belt is not required to be matched with the size of the workpiece, so that the conveying belt is required to be capable of adjusting the size to adapt to the conveying belt with different sizes, and the development of the radiating fin centralized material collecting system is necessary.

Disclosure of Invention

The invention aims to provide a concentrated material collecting system for cooling fins, which solves the technical problems of large occupied area and lack of adjusting function of a conveying belt in the prior art.

In order to solve the technical problems, the invention provides a concentrated material collecting system for radiating fins, which comprises:

the device comprises a supporting frame, a conveying part, a lifting part and a cooling part, wherein the supporting frame comprises a plurality of cross beams and a plurality of longitudinal beams, and the supporting frame is of a frame structure;

the conveying part is arranged at the upper end of the supporting frame and is suitable for conveying workpieces;

the lifting part is fixed at one end of the supporting frame, the lifting part is matched with the conveying part, and a detection device is fixed at the upper end of the lifting part;

the cooling part is rectangular, the cooling part is hollow, the cooling part is suitable for cooling a workpiece, wherein

When the workpiece is placed in the cooling part, the cooling part is suitable for cooling the workpiece;

the conveying part is suitable for conveying the cooling part placed at the upper end of the conveying part to the lifting part;

the lifting part lifts the cooling part upwards to detect whether the cooling of the workpiece in the cooling part is qualified.

Preferably, the conveying section includes: the conveying motor is fixed at one end of the supporting frame far away from the lifting part, the driven shaft is linked with the conveying motor, the driven shaft is rotatably arranged at one side of the conveying motor, and two ends of the driven shaft are respectively linked with the two circulating belts;

the circulating belt is arranged along the length direction of the supporting frame;

the adjusting assemblies are slidably arranged on the outer sides of the supporting frames, the adjusting assemblies are arranged above the circulating belt, and the two adjusting assemblies are suitable for preventing workpieces from sliding off the circulating belt; wherein the method comprises the steps of

The conveying motor drives the two circulating belts to circularly rotate through a driven shaft so as to transport workpieces;

and adjusting the distance between the two adjusting assemblies to adapt to workpieces with different sizes.

Preferably, the adjusting assembly includes: the device comprises a limiting plate, a sliding rod, a first fixed block, an adjusting ring and an adjusting bolt, wherein the limiting plate is arranged along the length direction of the supporting frame and is arranged above the circulating belt;

the first fixing block is fixed on the outer side wall of the limiting plate, and the sliding rod is vertically fixed on the inner side wall of the first fixing block;

the adjusting rings are fixed on the outer side wall of the supporting frame, the sliding rods can be inserted into the adjusting rings in a sliding mode, one adjusting ring corresponds to one sliding rod, and the adjusting bolts are rotatably arranged on the outer wall of the adjusting ring; wherein the method comprises the steps of

When the adjusting bolt is rotated to a loosening state, the sliding rod is slid to adjust the distance between the two limiting plates which are oppositely arranged.

Preferably, two ends of the limiting plate are respectively provided with a drainage block, and the drainage blocks are arranged in an outward inclined manner from the end parts of the limiting plate.

Preferably, the lifting part includes: lifting cylinder, supporting plate and several guide posts,

the lifting cylinder is vertically fixed at the lower part of the supporting frame, the supporting plate is arranged above the supporting frame, and the end part of a piston rod of the lifting cylinder is fixed at the lower end of the supporting plate;

the guide columns are arranged at the lower end of the supporting plate in a matrix manner, guide rings matched with the guide columns are arranged on the supporting frame, and the guide columns are slidably arranged in the guide rings; wherein the method comprises the steps of

The lifting cylinder drives the supporting plate to move upwards so that the cooling part is in contact with the detection device to detect whether the cooling of the workpiece in the cooling part is qualified or not.

Preferably, the lifting part further comprises a plurality of auxiliary plates slidably arranged on the inner side wall of the support frame, the auxiliary plates are vertically arranged, wherein

The two auxiliary plates which are oppositely arranged are adjusted to slide relatively or slide relatively apart so as to adapt to the outer walls of the cooling parts with different sizes.

Preferably, the support frame is further provided with a plurality of protection nets, and the protection nets are arranged above the lifting part.

Preferably, the cooling unit includes: the cooling box is rectangular, the cooling box is hollow, and a placing opening suitable for placing and taking a workpiece is formed in the side wall of the cooling box;

the circulating water pump is fixed at the upper end of the cooling box, two cooling water tanks are symmetrically arranged at two sides of the circulating water pump, and the cooling water tanks are communicated with the circulating water pump;

the water outlet pipe is fixed at one side of the cooling water tank far away from the circulating water pump, and is suitable for injecting cooling water into the cooling tank wall and the cooling tank;

a second fixed block is fixed on two sides of each cooling water tank, and the cooling water tanks are linked with the second fixed blocks through rotating shafts;

the linkage assembly is arranged in the cooling box in a lifting manner, and the upper end of the linkage assembly protrudes out of the cooling box and is linked with the end part of the cooling water box;

the recovery tank is arranged at the lower end of the cooling box in a hollow columnar shape, and cooling water finally flows into the recovery tank in a converging manner;

the side wall of the recovery tank is fixedly provided with a linkage rod, the interior of the linkage rod is hollow, the linkage rod is communicated with the recovery tank, and the upper end of the linkage rod is arranged below the linkage assembly; wherein the method comprises the steps of

The workpiece is placed in the cooling box and extrudes the linkage assembly, and the linkage assembly slides downwards to drive the cooling water tank to rotate by taking the rotating shaft as an axis, so that the water outlet pipe injects water into the cooling box to spray the workpiece;

when the lifting cylinder drives the cooling box to move upwards to the detection device, the detection device is suitable for detecting whether the cooling of the workpiece reaches a qualified value;

after the workpiece is cooled and qualified, the lifting cylinder drives the cooling water tank to move downwards to the lower end of the recovery tank to prop against the cross beam of the support frame, and the linkage rod pushes the workpiece upwards so that the inner end part of the workpiece is tilted upwards.

Preferably, the linkage assembly includes: the linkage bar is C-shaped, the linkage bar is arranged in the cooling box in a lifting manner, and an opening of the linkage bar is suitable for placing workpieces;

the connecting block is fixed at the upper end of the linkage bar, protrudes out of the outer wall of the cooling tank, and is contacted with the side wall of the cooling water tank;

a plurality of spray pipes are arranged in the cooling box, one spray pipe corresponds to one water outlet pipe, and a water inlet of the spray pipe is arranged below the water outlet pipe; wherein the method comprises the steps of

When the workpiece extrudes the linkage bar to move downwards, the linkage bar presses the cooling water tank downwards through the connecting block to rotate towards the water outlet pipe;

the water outlet end of the water outlet pipe is inserted into the water inlet of the spray pipe so as to spray cooling water to the workpiece.

Preferably, the upper end of the outer wall of the cooling box is provided with a plurality of cooling water gaps communicated with the inner wall of the cooling box, the side wall and the bottom wall of the cooling box are provided with a plurality of cooling pipelines communicated with the cooling water gaps, and the cooling pipelines are mutually communicated;

the linkage rod is slidably inserted into any cooling pipeline, and the side wall of the linkage rod is provided with a water outlet communicated with the linkage pipeline; wherein;

when the cooling box slides downwards to the position that the recovery tank is propped against the bottom wall of the support frame, the cooling box continuously moves downwards so as to enable the linkage rod to move upwards to push the workpiece so as to enable the end part of the workpiece to tilt;

when the linkage rod moves upwards, the water outlet on the side wall of the linkage rod is communicated with the cooling pipeline, so that cooling water in the cooling pipeline flows into the cooling pool.

The cooling fin centralized material collecting system has the beneficial effects that the cooling water in the cooling water tank is communicated with the spray pipe through the water outlet pipe and sprays cooling water to the upper surface of the workpiece to achieve the effect of cooling the workpiece, and the cooling water is recycled and used after being recycled and cooled through the recycling tank; the lifting part is matched with the conveying part, the workpiece is cooled in the cooling part, the conveying part conveys the cooling part to the lifting part, the lifting part lifts the cooling part to enable the detection device to detect the temperature of the workpiece in the cooling box, after the workpiece is cooled to a designated stable state, the lifting part is contracted downwards to the lower end of the recovery tank to be propped against the side wall of the support frame, and at the moment, a linkage rod fixed on the outer wall of the recovery tank is lifted upwards to push the end part of the workpiece to tilt, so that the workpiece is convenient to discharge; meanwhile, the water outlet of the cooling channel is opened by the linkage rod, so that cooling water in the side wall and the bottom wall of the cooling box is discharged into the recovery pond through the linkage rod, the cooling efficiency of the workpiece is greatly improved, and meanwhile, the occupied space of equipment is saved.

Drawings

The invention will be further described with reference to the drawings and examples.

FIG. 1 is a perspective view of a preferred embodiment of a fin collection system of the present invention;

fig. 2 is a perspective view of a preferred embodiment of the delivery section of the present invention;

fig. 3 is a perspective view of the lifting part of the present invention;

fig. 4 is a front view of the cooling portion of the present invention;

fig. 5 is a perspective view of a cooling portion of the present invention;

FIG. 6 is a front view of the linkage assembly of the present invention;

fig. 7 is a front view of the recovery tank of the present invention.

In the figure:

1. a support frame; 11. a protective net; 12. a detection device;

2. a conveying section; 21. a conveying motor; 22. a driven shaft; 23. a circulating belt; 24. an adjustment assembly; 241. a limiting plate; 242. a slide bar; 243. a first fixed block; 244. an adjusting ring; 245. an adjusting bolt; 246. a drainage block;

3. a lifting part; 31. a lifting cylinder; 32. a support plate; 33. a guide post; 34. a guide ring; 35. an auxiliary plate;

4. a cooling unit; 41. a cooling box; 42. a linkage assembly; 421. a linkage bar; 422. a connecting block; 43. a circulating water pump; 44. a cooling water tank; 441. a second fixed block; 442. a rotating shaft; 45. a water outlet pipe; 451. a control device; 46. a recovery pool; 47. a linkage rod; 48. a water collection tank; 49. a cooling water port; 50. a spray header.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the invention and therefore show only the structures which are relevant to the invention.

As shown in fig. 1 to 7, a fin concentrated material collecting system of the present invention includes: the device comprises a support frame 1, a conveying part 2, a lifting part 3 and a cooling part 4, wherein the support frame 1 comprises a plurality of cross beams and a plurality of longitudinal beams, and the support frame 1 is of a frame structure; the conveying part 2 is arranged along the length direction of the support frame 1, the conveying part 2 is arranged at the upper end of the support frame 1, and the conveying part 2 is suitable for conveying workpieces; the lifting part 3 is fixed at one end of the supporting frame 1, the lifting part 3 is fixed at the tail end of the supporting frame 1, which is close to the conveying part 2, after the workpiece is placed on the conveying part 2, the conveying part 2 is suitable for conveying the workpiece to the lifting part 3, the horizontal height of the contracted state of the lifting part 3 is smaller than that of the conveying part 2, so that when the conveying part 2 moves the workpiece to the position above the lifting part 3, the lifting part 3 can lift the workpiece upwards from the bottom; a detection device 12 is fixed at the upper end of the lifting part 3; the detection device 12 is arranged at the upper end of the lifting part 3, so that on one hand, the workpiece has enough cooling time in the cooling part 4, and on the other hand, the occupied area of the equipment is reduced; the cooling part 4 is rectangular, the inside of the cooling part 4 is hollow, the cooling part 4 is suitable for cooling a workpiece, wherein the cooling part 4 continuously sprays and cools the workpiece in the process that the workpiece moves on the conveying part 2, and the cooling part 4 is suitable for cooling the workpiece when the workpiece is placed in the cooling part 4; the conveying part 2 is suitable for conveying the cooling part 4 placed at the upper end of the conveying part to the lifting part 3; the lifting part 3 lifts the cooling part 4 upwards to detect whether the cooling of the workpiece in the cooling part 4 is qualified. The invention has simple structure and convenient operation, after the workpiece is put into the cooling part 4 by the cooperation of the lifting part 3, the conveying part 2 and the cooling part 4, the cooling part 4 sprays and cools the workpiece, the conveying part 2 synchronously drives the workpiece to move to the blanking station, when the workpiece moves to the lifting part 3, the lifting part 3 lifts the workpiece upwards to enable the detection device 12 to detect the cooling condition of the workpiece, and when the cooling condition of the workpiece reaches the specified temperature, the lifting part 3 drives the cooling part 4 to move downwards to blanking; when the workpiece is cooled and the temperature does not reach the designated temperature, the lifting part 3 is kept in a lifting state until the cooling part 4 sprays and cools the temperature of the workpiece to the designated temperature, the lifting part 3 drives the workpiece to move downwards to discharge, and compared with the traditional conveyor belt which needs a long conveyor belt to transport the workpiece, the conveyor belt disclosed by the invention has the advantages that the occupied area is small, and the production cost is saved.

Preferably, the conveying section 2 includes: the conveying motor 21, the driven shaft 22, two circulating belts 23 and two adjusting assemblies 24, wherein the conveying motor 21 is fixed at one end of the supporting frame 1 far away from the lifting part 3, the driven shaft 22 is linked with the conveying motor 21, the driven shaft 22 is rotatably arranged at one side of the conveying motor 21, the driven shaft 22 is parallel to the rotating shaft of the conveying motor 21, and the driven shaft 22 is meshed with the rotating shaft of the conveying motor 21 through a transmission chain; the driven shaft 22 is rotatably arranged on the inner side of the support frame 1, driven wheels are sleeved at two ends of the driven shaft 22 respectively, and the circulating belt 23 is in transmission connection with the driven wheels; the two ends of the driven shaft 22 are respectively linked with the two circulating belts 23, when the conveying motor 21 works, the driven wheel is driven by the transmission chain to rotate circumferentially, and the driven shaft 22 synchronously drives the two driven wheels to rotate circumferentially so as to drive the two circulating belts 23 to move circularly. The circulating belts 23 are arranged along the length direction of the support frame 1, and when the cooling device is in operation, two ends of the cooling part 4 are placed at the upper ends of the two circulating belts 23, and the circulating belts 23 move horizontally to drive the cooling part 4 to move towards the lifting part 3.

In order to improve the stability of the movement of the cooling part 4 on the circulating belt 23, the adjusting assemblies 24 are slidably arranged outside the supporting frame 1, the two adjusting assemblies 24 are oppositely arranged, the adjusting assemblies 24 are arranged above the circulating belt 23, and the two adjusting assemblies 24 are suitable for blocking the workpiece from sliding off the circulating belt 23; wherein the conveying motor 21 drives the two circulating belts 23 to circularly rotate through the driven shaft 22 so as to convey workpieces; the spacing between the two adjustment assemblies 24 is adjusted to accommodate workpieces of different sizes. Specifically, the adjustment assembly 24 includes: the limiting plate 241, the sliding rod 242, the first fixed block 243, the adjusting ring 244 and the adjusting bolt 245, wherein the limiting plate 241 is arranged along the length direction of the supporting frame 1, and the limiting plate 241 is arranged above the circulating belt 23; the both ends of limiting plate 241 are provided with a drainage piece 246 respectively, the drainage piece 246 sets up from limiting plate 241 tip outside slope, and the setting of drainage piece 246, when cooling portion 4 is close limiting plate 241 and keep away from limiting plate 241, the stability that cooling portion 4 removed can be improved to the drainage piece 246. The first fixing block 243 is fixed on the outer side wall of the limiting plate 241, and the sliding rod 242 is vertically fixed on the inner side wall of the first fixing block 243; two first fixing blocks 243 are respectively fixed at two ends of each limiting plate 241, and the sliding rods 242 are vertically fixed on the inner side walls of the first fixing blocks 243; the adjusting ring 244 is fixed on the outer side wall of the supporting frame 1, a through hole matched with the sliding rod 242 is formed in the supporting frame 1, the sliding rod 242 can be slidably inserted into the adjusting ring 244 and pass through the through hole, one adjusting ring 244 corresponds to one sliding rod 242, and the adjusting bolt 245 is rotatably arranged on the outer wall of the adjusting ring 244; when the adjusting bolt 245 is rotated to a loose state, the sliding rod 242 is slid to adjust the distance between the two opposite limiting plates 241. When the distance between the two opposite limiting plates 241 needs to be adjusted, the adjusting bolt 245 is rotated to be in a loose state, the sliding rod 242 is slid outwards or inwards to increase or decrease the distance between the two limiting plates 241, and the adjusting bolt 245 is tightened again to fixedly connect the sliding rod 242 with the adjusting ring 244.

Optionally, the lifting part 3 includes: the lifting device comprises a lifting cylinder 31, a supporting plate 32 and a plurality of guide posts 33, wherein the lifting cylinder 31 is vertically fixed at the lower part of the supporting frame 1, the supporting plate 32 is arranged above the supporting frame 1, and the end part of a piston rod of the lifting cylinder 31 is fixed at the lower end of the supporting plate 32; the lifting cylinder 31 can drive the supporting plate 32 to vertically slide up and down; the guide posts 33 are arranged at the lower end of the supporting plate 32 in a matrix manner, guide rings 34 matched with the guide posts 33 are arranged on the supporting frame 1, and the guide posts 33 are slidably arranged in the guide rings 34; wherein the lifting cylinder 31 drives the supporting plate 32 to move upwards so as to enable the cooling part 4 to be in contact with the detection device 12, and thus whether the workpiece in the cooling part 4 is cooled or not is detected to be qualified. The guide posts 33 are guided to be fixed at four right-angle edges of the support plate 32, and when the lifting cylinder 31 drives the support plate 32 to vertically slide up and down, the guide posts 33 follow the support plate 32 to vertically slide up and down synchronously, so that the stability of the support plate 32 in the vertical movement process is improved. The lifting part 3 further comprises a plurality of auxiliary plates 35, the auxiliary plates 35 are slidably arranged on the inner side walls of the supporting frame 1, the auxiliary plates 35 are vertically arranged, and the two oppositely arranged auxiliary plates 35 are adjusted to slide relatively or slide relatively away from each other so as to adapt to the outer walls of the cooling parts 4 with different sizes. The support frame 1 is also provided with a plurality of protective nets 11, and the protective nets 11 are arranged above the lifting part 3. The arrangement of the protection net 11 and the auxiliary plate 35 is on the one hand to improve the stability of the cooling part 4 in the lifting process, especially the arrangement of the auxiliary plate 35, the auxiliary plate 35 is arranged on three sides of the lifting plate, and the auxiliary plate 35 is adjusted to slide inwards to make the side wall of the auxiliary plate 35 fit with the side wall of the cooling part 4, thereby ensuring the stability of the lifting part 3 in the lifting process.

The detection device 12 is rectangular, the detection device 12 is horizontally arranged, the detection device 12 is a temperature detector, when the lifting cylinder 31 drives the cooling part 4 to move to one side of the detection device 12, the detection device 12 can detect the temperature of a workpiece in the cooling part 4, and meanwhile, the detection device 12 can also detect the temperature of an external box body of the cooling part 4.

Preferably, the cooling unit 4 includes: the cooling box 41, the linkage assembly 42, the circulating water pump 43, two cooling water tanks 44, a water outlet pipe 45 and a recovery tank 46, wherein the cooling box 41 is rectangular, the inside of the cooling box 41 is hollow, and a placing opening suitable for placing and taking a workpiece is formed in the side wall of the cooling box 41; the work piece is placed into through placing the mouth level the cooling is inwards, place the mouth diapire and be provided with a manger plate strip under, when the outlet pipe 45 water injection sprays the work piece to cooling box 41, the manger plate strip can stop the cooling water and outwards flow from placing the mouth. The circulating water pump 43 is fixed at the upper end of the cooling tank 41, the water outlet of the circulating water pump 43 is communicated with two cooling water tanks 44, the water inlet of the circulating water pump 43 is communicated with the recovery tank 46, the circulating water pump 43 can pump cooling water in the recovery tank 46 to the cooling water tanks 44, spray the cooling water to a workpiece through the water outlet pipe 45 or inject the cooling water into the side wall of the cooling tank 41, and finally the cooling water flows back to the recovery tank 46. Two cooling water tanks 44 are symmetrically arranged at two sides of the circulating water pump 43, and the cooling water tanks 44 are communicated with the circulating water pump 43; the water outlet pipe 45 is fixed at a side of the cooling water tank 44 away from the circulating water pump 43. A water collecting tank 48 is arranged at the upper end of the outer wall of the cooling tank 41, a plurality of cooling water ports 49 are arranged at the lowest point of the water collecting tank 48, a plurality of cooling pipelines communicated with the cooling water ports 49 are arranged on the side wall and the bottom wall of the cooling tank 41, and the cooling pipelines are mutually communicated; after the cooling water discharged from the water outlet pipe 45 is injected into the water collecting tank 48, the cooling water is injected into the cooling pipes positioned in the side wall and the bottom wall of the cooling box 41 through the cooling water opening 49, so that the cooling box 41 is cooled. When no work is placed in the cooling tank 41, the water outlet pipe 45 always injects cooling water into the water collection tank 48. A plurality of spray pipes are arranged in the cooling box 41, one spray pipe corresponds to one water outlet pipe 45, and a water inlet of the spray pipe is arranged below the water outlet pipe 45; the inner wall of the cooling box 41 is provided with a plurality of spray heads 50, one spray head 50 corresponds to one spray pipe, and the spray heads 50 are suitable for spraying cooling water to the upper surface of the workpiece so as to cool the workpiece. When a workpiece is placed in the cooling box 41, the workpiece extrudes the linkage assembly 42 to enable the cooling water tank 44 to axially rotate, the cooling water tank 44 drives the water outlet pipe 45 to be inserted into the water inlet of the spray pipe, and cooling water in the cooling water tank 44 is sprayed to the workpiece through the spray header 50 for cooling. A second fixing block 441 is fixed on both sides of each cooling water tank 44, and the cooling water tanks 44 are linked with the second fixing blocks 441 through rotating shafts 442; the rotating shaft 442 is fixed at one end of the second fixing block 441 away from the circulating water pump 43, when the linkage assembly 42 drives the cooling water tank 44 to rotate in a downward arc with the rotating shaft 442 as a fulcrum, the rotation angle of the cooling water tank 44 is smaller, so that the vibration of the cooling water tank 44 to the cooling water tank 41 is also minimal. In order to prevent the water outlet pipe 45 from splashing due to the up-and-down rotation along with the circular arc of the cooling water tank 44, a control device 451 is further arranged at the end part of the water outlet pipe 45, which is close to the cooling water tank 44, and the control device 451 can control and reduce the water outlet amount of the water outlet pipe 45 in the process that the water outlet pipe 45 rotates along with the upward or downward circular arc of the cooling water tank 44; and when the water outlet pipe 45 stops rotating, the control device 451 releases the control of the water outlet amount of the water outlet pipe 45.

In order to control the water outlet direction of the water outlet pipe 45, the linkage assembly 42 is arranged in the cooling tank 41 in a lifting manner, and the upper end of the linkage assembly 42 protrudes out of the cooling tank 41 and is linked with the end part of the cooling water tank 44; specifically, the linkage assembly 42 includes: the linkage bar 421 and the connecting block 422, wherein the linkage bar 421 is in a shape of C, the linkage bar 421 is arranged in the cooling box 41 in a lifting manner, and an opening of the linkage bar 421 is suitable for placing a workpiece; the connecting block 422 is fixed at the upper end of the linkage bar 421, the connecting block 422 protrudes out of the outer wall of the cooling tank 41, and the connecting block 422 contacts with the side wall of the cooling water tank 44; after the workpiece is placed in the lower section of the linkage bar 421, the linkage bar 421 is extruded to move vertically downwards under the action of the gravity of the workpiece, the linkage bar 421 synchronously pulls the connecting block 422 to move vertically downwards, the connecting block 422 presses the end part of the cooling water tank 44 to move downwards in an arc with the rotating shaft 442 as a fulcrum, the cooling water tank 44 synchronously drives the water outlet pipe 45 to move downwards in an arc, and the water outlet of the water outlet pipe 45 is inserted into the water inlet of the spray pipe so that cooling water in the cooling water tank 44 is sprayed to the workpiece through the spray pipe; a plurality of spray pipes are arranged in the cooling box 41, one spray pipe corresponds to one water outlet pipe 45, and a water inlet of the spray pipe is arranged below the water outlet pipe 45; when the workpiece extrudes the linkage bar 421 to move downwards, the linkage bar 421 presses the cooling water tank 44 downwards through the connecting block 422 to rotate towards the water outlet pipe 45; the water outlet end of the water outlet pipe 45 is inserted into the water inlet of the spray pipe to spray cooling water to the workpiece. After the workpiece is discharged from the cooling tank 41, the cooling water tank 44 drives the water outlet pipe 45 to move upwards in an arc by taking the rotating shaft 442 as a fulcrum under the action of self gravity, so that the linkage assembly 42 is pulled upwards to be restored to an initial state. The cooling water discharged from the water outlet pipe 45 at this time is injected into the water collecting tank 48, and is injected into the side wall and the bottom wall of the cooling tank 41 through the cooling water port 49.

In order to improve the utilization efficiency of the cooling water, a recovery tank 46 is further arranged at the lower bottom of the cooling tank 41, and the recovery tank 46 is communicated with the circulating water pump 43; the recovery tank 46 is arranged at the lower end of the cooling tank 41 in a hollow column shape, and the cooling water finally flows into the recovery tank 46 in a converging manner; the bottom wall of the cooling tank 41 is arranged obliquely, a water return port is arranged at the lowest position of the bottom wall of the cooling tank 41, the recovery tank 46 is arranged below the water return port, and cooling water sprayed out by the spray pipe flows to the water return port and flows into the recovery tank 46 through the water return port.

The side wall of the recovery tank 46 is fixedly provided with a linkage rod 47, the interior of the linkage rod 47 is hollow, the lower end of the linkage rod 47 is communicated with the recovery tank 46, the upper end of the linkage rod 47 is arranged in any cooling pipeline, the upper end of the linkage rod 47 protrudes out of the inner bottom wall of the cooling tank 41, the side wall of the linkage rod 47 is provided with a water outlet communicated with the cooling pipeline, when a workpiece is placed in the cooling tank 41, the inner end of the workpiece is placed above the linkage rod 47, at the moment, the linkage rod 47 is not communicated with the cooling pipeline, and the linkage rod 47 has the effect of sealing the water outlet of the cooling pipeline; when the detection assembly detects that the workpiece is cooled to reach the specified temperature, the lifting cylinder 31 drives the supporting plate 32 to move downwards until the lower end of the recovery tank 46 abuts against the side wall of the supporting frame 1, the supporting plate 32 continues to move downwards, at the moment, the upper end of the recovery tank 46 abuts against the bottom wall of the cooling box 41, at the moment, the linkage rod 47 abuts against the bottom wall of the inner end of the workpiece and lifts the inner end of the workpiece upwards, so that the workpiece is convenient to slide outwards from the cooling box 41; when the linkage rod 47 lifts up the workpiece, the water outlet of the linkage rod 47 is communicated with the cooling pipeline, and the cooling water in the side wall and the bottom wall of the cooling box 41 flows into the recovery tank 46 synchronously.

The above-described preferred embodiments according to the present invention are intended to suggest that, in view of the above description, various changes and modifications may be made by the worker in question without departing from the scope of the technical idea of the present invention. The technical scope of the present invention is not limited to the description, but must be determined according to the scope of claims.

Claims (7)

1. A fin concentrate collection system, comprising:

the device comprises a supporting frame, a conveying part, a lifting part and a cooling part, wherein the supporting frame comprises a plurality of cross beams and a plurality of longitudinal beams, and the supporting frame is of a frame structure;

the conveying part is arranged at the upper end of the supporting frame and is suitable for conveying workpieces;

the lifting part is fixed at one end of the supporting frame, the lifting part is matched with the conveying part, and a detection device is fixed at the upper end of the lifting part;

the cooling part is rectangular, the cooling part is hollow, the cooling part is suitable for cooling a workpiece, wherein

When the workpiece is placed in the cooling part, the cooling part is suitable for cooling the workpiece;

the conveying part is suitable for conveying the cooling part placed at the upper end of the conveying part to the lifting part;

the lifting part lifts the cooling part upwards to detect whether the cooling of the workpiece in the cooling part is qualified or not;

the cooling section includes: the cooling box is rectangular, the cooling box is hollow, and a placing opening suitable for placing and taking a workpiece is formed in the side wall of the cooling box;

the circulating water pump is fixed at the upper end of the cooling box, two cooling water tanks are symmetrically arranged at two sides of the circulating water pump, and the cooling water tanks are communicated with the circulating water pump;

the water outlet pipe is fixed at one side of the cooling water tank far away from the circulating water pump, and is suitable for injecting cooling water into the cooling tank wall and the cooling tank;

a second fixed block is fixed on two sides of each cooling water tank, and the cooling water tanks are linked with the second fixed blocks through rotating shafts;

the linkage assembly is arranged in the cooling box in a lifting manner, and the upper end of the linkage assembly protrudes out of the cooling box and is linked with the end part of the cooling water box;

the recovery tank is arranged at the lower end of the cooling box in a hollow columnar shape, and cooling water finally flows into the recovery tank in a converging manner;

the side wall of the recovery tank is fixedly provided with a linkage rod, the interior of the linkage rod is hollow, the linkage rod is communicated with the recovery tank, and the upper end of the linkage rod is arranged below the linkage assembly; wherein the method comprises the steps of

The workpiece is placed in the cooling box and extrudes the linkage assembly, and the linkage assembly slides downwards to drive the cooling water tank to rotate by taking the rotating shaft as an axis, so that the water outlet pipe injects water into the cooling box to spray the workpiece;

when the lifting cylinder drives the cooling box to move upwards to the detection device, the detection device is suitable for detecting whether the cooling of the workpiece reaches a qualified value;

after the workpiece is cooled and qualified, the lifting cylinder drives the cooling water tank to move downwards to the lower end of the recovery tank to prop against the cross beam of the support frame, and the linkage rod pushes the workpiece upwards so that the inner end part of the workpiece is tilted upwards;

the linkage assembly includes: the linkage bar is C-shaped, the linkage bar is arranged in the cooling box in a lifting manner, and an opening of the linkage bar is suitable for placing workpieces;

the connecting block is fixed at the upper end of the linkage bar, protrudes out of the outer wall of the cooling tank, and is contacted with the side wall of the cooling water tank;

a plurality of spray pipes are arranged in the cooling box, one spray pipe corresponds to one water outlet pipe, and a water inlet of the spray pipe is arranged below the water outlet pipe; wherein the method comprises the steps of

When the workpiece extrudes the linkage bar to move downwards, the linkage bar presses the cooling water tank downwards through the connecting block to rotate towards the water outlet pipe;

the water outlet end of the water outlet pipe is inserted into the water inlet of the spray pipe so as to spray cooling water to the workpiece;

the upper end of the outer wall of the cooling box is provided with a plurality of cooling water gaps communicated with the inner wall of the cooling box, the side wall and the bottom wall of the cooling box are provided with a plurality of cooling pipelines communicated with the cooling water gaps, and the cooling pipelines are mutually communicated;

the linkage rod is slidably inserted into any cooling pipeline, and the side wall of the linkage rod is provided with a water outlet communicated with the linkage pipeline; wherein;

when the cooling box slides downwards to the position that the recovery tank is propped against the bottom wall of the support frame, the cooling box continuously moves downwards so as to enable the linkage rod to move upwards to push the workpiece so as to enable the end part of the workpiece to tilt;

when the linkage rod moves upwards, the water outlet on the side wall of the linkage rod is communicated with the cooling pipeline, so that cooling water in the cooling pipeline flows into the cooling pool.

2. A fin stock collection system as recited in claim 1, wherein,

the conveying section includes: the conveying motor is fixed at one end of the supporting frame far away from the lifting part, the driven shaft is linked with the conveying motor, the driven shaft is rotatably arranged at one side of the conveying motor, and two ends of the driven shaft are respectively linked with the two circulating belts;

the circulating belt is arranged along the length direction of the supporting frame;

the adjusting assemblies are slidably arranged on the outer sides of the supporting frames, the adjusting assemblies are arranged above the circulating belt, and the two adjusting assemblies are suitable for preventing workpieces from sliding off the circulating belt; wherein the method comprises the steps of

The conveying motor drives the two circulating belts to circularly rotate through a driven shaft so as to transport workpieces;

and adjusting the distance between the two adjusting assemblies to adapt to workpieces with different sizes.

3. A fin stock collection system as recited in claim 2, wherein,

the adjustment assembly includes: the device comprises a limiting plate, a sliding rod, a first fixed block, an adjusting ring and an adjusting bolt, wherein the limiting plate is arranged along the length direction of the supporting frame and is arranged above the circulating belt;

the first fixing block is fixed on the outer side wall of the limiting plate, and the sliding rod is vertically fixed on the inner side wall of the first fixing block;

the adjusting rings are fixed on the outer side wall of the supporting frame, the sliding rods can be inserted into the adjusting rings in a sliding mode, one adjusting ring corresponds to one sliding rod, and the adjusting bolts are rotatably arranged on the outer wall of the adjusting ring; wherein the method comprises the steps of

When the adjusting bolt is rotated to a loosening state, the sliding rod is slid to adjust the distance between the two limiting plates which are oppositely arranged.

4. A fin stock collection system as recited in claim 3, wherein,

the two ends of the limiting plate are respectively provided with a drainage block, and the drainage blocks are arranged from the end parts of the limiting plate in an outward inclined manner.

5. A fin stock collection system as recited in claim 4, wherein,

the lifting part comprises: lifting cylinder, supporting plate and several guide posts,

the lifting cylinder is vertically fixed at the lower part of the supporting frame, the supporting plate is arranged above the supporting frame, and the end part of a piston rod of the lifting cylinder is fixed at the lower end of the supporting plate;

the guide columns are arranged at the lower end of the supporting plate in a matrix manner, guide rings matched with the guide columns are arranged on the supporting frame, and the guide columns are slidably arranged in the guide rings; wherein the method comprises the steps of

The lifting cylinder drives the supporting plate to move upwards so that the cooling part is in contact with the detection device to detect whether the cooling of the workpiece in the cooling part is qualified or not.

6. A fin stock collection system as recited in claim 5, wherein,

the lifting part further comprises a plurality of auxiliary plates, the auxiliary plates are slidably arranged on the inner side wall of the supporting frame, and the auxiliary plates are vertically arranged, wherein

The two auxiliary plates which are oppositely arranged are adjusted to slide relatively or slide relatively apart so as to adapt to the outer walls of the cooling parts with different sizes.

7. A fin stock collection system as recited in claim 6, wherein,

the support frame is also provided with a plurality of protective nets, and the protective nets are arranged above the lifting part.

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