CN214950808U - Improved generation heat transfer fin production facility - Google Patents

Abstract

The utility model discloses an improved generation heat transfer fin production facility relates to heat transfer fin production facility technical field, specifically is to support base, guiding mechanism, roof and push pedal mechanism, the left front side and the right rear side of supporting the base all are provided with the pneumatic cylinder, the top center of supporting the base is fixed with the gas base, the top of gas base is fixed with the lower mould supporting seat, guiding mechanism is vertical respectively and settles both sides about the top of supporting the base, the roof sets up the top at guiding mechanism, push pedal mechanism settles both sides around the upper die base respectively. This improved generation heat transfer fin production facility, except being equipped with two direction and buffer structure, still be equipped with two moulding-dies and lift mould power structure, for going up the reciprocating of mould part and provide good helping hand, avoid production facility because of the ageing problem that the mould action that opens and shuts that appears is not coherent, untimely, effectively prolonged this improved generation heat transfer fin production facility's life and comprehensive use effect.

Description

Improved generation heat transfer fin production facility

Technical Field

The utility model relates to a heat transfer fin production facility technical field specifically is an improved generation heat transfer fin production facility.

Background

The metal sheet with strong heat conductivity which is additionally arranged on the surface of the heat exchange device needing heat transfer is a heat exchange fin, the fin can increase the heat exchange surface area of the heat exchange device, and is one of very important components for the heat exchange device, and metal materials with good heat conduction effects are selected for the common heat exchange fins.

The fin needs to be produced through special mould, and the production and processing of general fin all is continuous, and its shaping mode is also mostly the mould pressfitting and forms.

The existing heat exchange fin production equipment has the advantages that in the fin production process, the opening and closing action of the die is prolonged along with the service life of the die, certain time delay can occur due to the influence of factors such as die abrasion, namely, in the die opening and closing process, the die cannot be opened and closed stably in time due to insufficient movement of a power mechanism.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides an improved generation heat transfer fin production facility has solved the problem of proposing in the above-mentioned background art.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: an improved heat exchange fin production device comprises a supporting base, a guide mechanism, a top plate and a push plate mechanism, wherein hydraulic cylinders are arranged on the left front side and the right rear side of the supporting base, the output ends of the hydraulic cylinders are connected with hydraulic rods, an air base is fixed at the center of the upper part of the supporting base, air conveying holes penetrate through the front side surface of the air base at equal intervals, a lower die supporting seat is fixed above the air base, the guide mechanism is vertically arranged on the left side and the right side of the upper part of the supporting base respectively and consists of a guide pipe, a guide rod and a guide spring, the top plate is arranged at the top end of the guide mechanism, the top ends of the hydraulic rods are connected to the lower surfaces of the left side and the right side of the top plate respectively, pneumatic lifting rods are arranged on the left side and the right side of the lower part of the top plate and close to the vertical central line of the top plate, the bottom ends of the pneumatic lifting rods are connected with an upper die movable seat, the lower part of the upper die movable seat is fixed with an upper die base, a plate passing groove is formed in the lower part of the upper die base, the push plate mechanisms are respectively arranged on the front side and the rear side of the upper die base, and the push plate mechanisms are composed of a pressing pipe, a rocker arm, a connecting plate, a rotary rod, an installation sleeve and a micro motor.

Optionally, a conveyor belt is arranged inside the upper portion of the lower die supporting seat, two ends of a driving shaft of the conveyor belt are connected with transmission motors, and rectangular blocks are uniformly and alternately arranged on the belt surface of the conveyor belt.

Optionally, a lower die base plate is arranged above the conveyor belt, the bottom surface of the lower die base plate is matched with the rectangular blocks in size, an air transmission seat is fixed above the lower die base plate, and a lower die plate is arranged above the air transmission seat in a matched mode.

Optionally, the upper surface of biography gas seat evenly is provided with the cooperation groove, and the inner bottom in cooperation groove is personally submitted the rectangle form and all bonds and be fixed with the rubber filler strip, the inside of biography gas seat and with the relative department in cooperation groove position all is provided with the gas transmission pipeline, and the top of gas transmission pipeline all communicates there is the toper air flue, the inside of lower bolster evenly runs through there is the air flue, and passes the position one-to-one between air flue and the toper air flue, all be connected with the connecting pipe between gas transmission pipeline and the gas transmission hole.

Optionally, the bottom of the guide pipe is vertically welded on the upper surface of the support base, a guide rod vertically penetrates through the inside of the guide pipe, and a guide spring is connected between the bottom surface of the guide rod and the inner bottom surface of the guide pipe.

Optionally, the upper surface left and right sides of going up the mould sliding seat all is provided with the buffering inserted way, and the inside bottom of buffering inserted way all is fixed with buffer spring's one end, other fixedly connected with buffering guide arm is equallyd divide to buffer spring's the other end, and the buffering guide arm inserts the cooperation in the buffering inserted way to the equal welded fastening in top of buffering guide arm is on the lower surface of roof.

Optionally, the micro motors are fixed on the upper die base through the welding plates, the micro motors are symmetrical with respect to a vertical central line of the upper die base, and the middle of the pressure pipe is fixedly hoisted on the front side and the rear side of the upper die base through the welding plates.

Optionally, the bearing is sleeved on the outer sides of the two ends of the pressure pipe, the rocker arms are sleeved on the outer sides of the bearing, one side of the vertical central line of the pressure pipe is connected with the connecting plate by the end of the rocker arm, the two connecting plates are symmetrically arranged on the vertical central line of the pressure pipe, the rotating rod is connected between the connecting plates in a rotating mode, the centers of the two end faces of the rotating rod are fixed with the rotating shaft rod, the outer wall face of the rotating rod is crossed to form bristles, and the rotating shaft rod is equally divided into two parts and penetrates through the center of the connecting plate.

Optionally, the tip of change axle pole has all cup jointed little drive disk, and the outside of little drive disk all overlaps and is equipped with driving belt, driving belt's another all cup joints big drive disk, and the inner wall middle part of big drive disk all is fixed with the bull stick, the center of bull stick is equipped with the lasso, and the center of bull stick cup joints the output axle head at micro motor.

Optionally, the edge both sides face of bull stick all stands out there is the snap ring, and the left side of bull stick is provided with the installation cover, the terminal surface that the installation cover is close to the bull stick all is provided with the draw-in groove with the terminal surface of pressing the pipe to be close to the bull stick, and the snap ring is equallyd divide and is do not sliding fit in the draw-in groove.

The utility model provides an improved generation heat transfer fin production facility possesses following beneficial effect:

1. the improved heat exchange fin production equipment is provided with two guide and buffer structures and two pressing die lifting power structures, namely a hydraulic lifting structure consisting of a hydraulic cylinder and a hydraulic rod and a pneumatic lifting structure where a pneumatic lifting rod is positioned, wherein, the pneumatic lifting rod is used as the main power part of the upper die part and directly bears the die opening and closing pressure to ensure that the die opening and closing action can be smoothly and completely carried out, the hydraulic lifting structure composed of the hydraulic cylinder and the hydraulic rod is used as an auxiliary power part of the upper die part, the direct acting object is the top plate, the top plate is driven to ascend and descend, the upper die part is assisted to stably move up and down, good assistance is provided for the up-and-down movement of the upper die part, the problems that the die opening and closing actions of production equipment are not consistent and timely due to aging are avoided, and the service life and the comprehensive using effect of the improved heat exchange fin production equipment are effectively prolonged.

2. The improved heat exchange fin production equipment has the specific action object of the guide mechanism being the top plate, and the specific action object of the buffer part consisting of the buffer insert channel, the buffer spring and the buffer guide rod being the upper die part, the buffer insert channel and the buffer guide rod are mutually matched, so that the upper die movable seat can stably move up and down, the buffer spring enables the upper die movable seat to move up and down to have certain recovery performance, after the die is closed, the smooth completion of the die opening action can be facilitated, the buffer part consisting of the buffer insert channel, the buffer spring and the buffer guide rod is used as a main guide and reset structure of the upper die, the smooth continuous proceeding of the die opening and closing action is effectively ensured, the guide mechanism is used as an auxiliary guide and reset structure of the upper die, so that the problem of guide deviation or untimely die separation caused by abrasion after the production equipment is used for a long time is directly and effectively solved.

3. This improved generation heat transfer fin production facility, guiding mechanism is used for opening and shutting the mould in-process, the direction and the buffering of roof activity from top to bottom, wherein, the direction when the telescopic tube structure of constituteing by stand pipe and guide bar can be used to the roof activity from top to bottom, and the adding of guide spring establishes for have good flexible elasticity between stand pipe and the guide bar, borrow this elasticity, can effectively and well cushion the mould clamping pressure, make things convenient for the smooth serialization of die sinking action to go on, avoid the problem that the equipment appears the time delay and blocks pause even.

4. This improved generation heat transfer fin production facility through the setting of conveyer belt for whole lower mould structure is convenient for control convenient to use more, and the conveyer belt starts the back, can correspondingly drive the lower mould base plate of settling on it and pass the gas seat shift position, and then is convenient for change the mould, and can the shared position of quick adjustment mould, makes the mould can obtain quick position adjustment, thereby can produce the processing fast.

5. This improved generation heat transfer fin production facility, the cooperation groove is used for installing the lower bolster on the seat of biography gas steadily well, the setting of rubber filler strip, make leave certain buffering clearance between lower bolster and the seat of biography gas, the mutual influence that pressure brought when having avoided the compound die causes lower bolster and the seat of biography gas to appear the damage separately, and rubber filler strip forms a rectangle square frame, can effectively isolated air, make and to wear to realize that the gas circuit communicates with each other between air flue and the toper air flue, compressed air passes through the compression pipeline in the gas base, through the output of gas transmission hole, in leading-in gas transmission pipeline respectively by the connecting pipe again, through the toper air flue that can link up and wear the air flue, rise to the lower bolster top, utilize atmospheric pressure thrust, can jack up the heat transfer fin who presses well in order to break away from the lower bolster fast, thereby effectively improve heat transfer fin's machining efficiency.

6. This improved generation heat transfer fin production facility, the rocking arm can rotate on the basis of pressing the pipe, thereby can adjust the high position of connecting plate and rotary rod, utilize the position height of raising or reducing the rotary rod, push into between the mould with the panel of different thickness, the brush hair of rotary rod outer wall can increase the friction, thereby when making the rotary rod rotatory, can exert good thrust to panel, guarantee sending into in succession smoothly of panel, the rotary rod is at rotatory in-process, exert thrust to panel, supplementary panel gets into in the mould fast, the fin of gained is accomplished in production also from this structure export smoothly in the mould fast.

Drawings

FIG. 1 is a schematic view of a partial half-section structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is an enlarged schematic view of the structure at A of FIG. 1 according to the present invention;

FIG. 4 is an enlarged schematic view of the structure of FIG. 1 at B according to the present invention;

FIG. 5 is a schematic structural view of the guiding mechanism of the present invention;

FIG. 6 is a schematic structural view of the push plate mechanism of the present invention;

fig. 7 is an enlarged schematic structural view of the point C in fig. 6 according to the present invention.

In the figure: 1. a support base; 2. a hydraulic cylinder; 3. a hydraulic lever; 4. an air base; 5. a gas transmission hole; 6. a lower die supporting seat; 7. a conveyor belt; 8. a rectangular block; 9. a drive motor; 10. a lower die substrate; 11. a gas transmission seat; 12. a mating groove; 13. a rubber filler strip; 14. a gas transfer duct; 15. a tapered air passage; 16. a lower template; 17. a gas passing channel; 18. a guide mechanism; 19. a guide tube; 20. a guide bar; 21. a guide spring; 22. a top plate; 23. a pneumatic lifter; 24. an upper die movable seat; 25. buffering the inserting channel; 26. a buffer spring; 27. a buffer guide rod; 28. an upper die base; 29. a plate passing groove; 30. a push plate mechanism; 31. pressing a pipe; 32. a bearing; 33. a rocker arm; 34. a connecting plate; 35. a spindle rod; 36. rotating the rod; 37. brushing; 38. a small drive disk; 39. a drive belt; 40. a large transmission disc; 41. a rotating rod; 42. a snap ring; 43. installing a sleeve; 44. a card slot; 45. a micro motor; 46. and (4) connecting the pipes.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 7, the present invention provides a technical solution: an improved heat exchange fin production device comprises a supporting base 1, a guide mechanism 18, a top plate 22 and a push plate mechanism 30, wherein hydraulic cylinders 2 are arranged on the left front side and the right rear side of the supporting base 1, the output ends of the hydraulic cylinders 2 are connected with hydraulic rods 3, an air base 4 is fixed at the center of the upper part of the supporting base 1, air transmission holes 5 penetrate through the front side surface of the air base 4 at equal intervals, a lower die supporting seat 6 is fixed above the air base 4, a conveyor belt 7 is arranged inside the upper part of the lower die supporting seat 6, two ends of a driving shaft of the conveyor belt 7 are connected with transmission motors 9, rectangular blocks 8 are uniformly and alternately arranged on the belt surface of the conveyor belt 7, a lower die base plate 10 is arranged above the conveyor belt 7, the bottom surface of the lower die base plate 10 is matched with the rectangular blocks 8 in size, an air transmission seat 11 is fixed above the lower die base plate 10, and a lower die plate 16 is arranged above the air transmission seat 11 in a matched mode, the arrangement of the conveyor belt 7 enables the whole lower die structure to be more convenient to control and use, after the conveyor belt 7 is started, the lower die base plate 10 and the gas transmission seat 11 arranged on the conveyor belt can be correspondingly driven to move, so that the die is convenient to replace, and the occupied position of the die can be quickly adjusted, so that the die can be quickly adjusted in position, and therefore production and processing can be quickly carried out;

the upper surface of the gas transmission seat 11 is uniformly provided with matching grooves 12, the inner bottom surfaces of the matching grooves 12 are rectangular and are fixedly bonded with rubber gasket strips 13, gas transmission pipelines 14 are arranged in the gas transmission seat 11 and opposite to the matching grooves 12, conical air passages 15 are communicated above the gas transmission pipelines 14, air through passages 17 uniformly penetrate through the lower template 16, the air through passages 17 and the conical air passages 15 are in one-to-one correspondence, connecting pipes 46 are connected between the gas transmission pipelines 14 and the gas transmission holes 5, the matching grooves 12 are used for stably and well installing the lower template 16 on the gas transmission seat 11, the rubber gasket strips 13 are arranged, a certain buffer gap is reserved between the lower template 16 and the gas transmission seat 11, the lower template 16 and the gas transmission seat 11 are prevented from being damaged due to mutual influence caused by pressure during mold closing, the rubber gasket strips 13 form a rectangular frame, and can effectively isolate air, the air passage communication can be realized between the air passing passage 17 and the conical air passage 15, compressed air passes through a compressed pipeline in the air base 4, is output through the air transmission hole 5, is respectively led into the air transmission pipeline 14 through the connecting pipe 46, rises above the lower template 16 through the conical air passage 15 and the air passing passage 17 which can be communicated, and can quickly jack up the pressed heat exchange fin to be separated from the lower template 16 by utilizing air pressure thrust, so that the processing efficiency of the heat exchange fin is effectively improved;

the guide mechanisms 18 are respectively vertically arranged at the left side and the right side above the supporting base 1, the guide mechanisms 18 are composed of guide pipes 19, guide rods 20 and guide springs 21, the bottom ends of the guide pipes 19 are vertically welded on the upper surface of the supporting base 1, a guide rod 20 vertically penetrates through the inside of the guide pipe 19, a guide spring 21 is connected between the bottom surface of the guide rod 20 and the inner bottom surface of the guide pipe 19, the guide mechanism 18 is used for guiding and buffering the up-and-down movement of a top plate 22 in the die opening and closing process, wherein, the telescopic sleeve structure composed of the guide tube 19 and the guide rod 20 can be used for guiding the top plate 22 when moving up and down, due to the addition of the guide spring 21, the guide pipe 19 and the guide rod 20 have good telescopic elasticity, so that the elasticity can effectively and well buffer the mold clamping pressure, the mold opening action is conveniently and continuously performed, and the problem of time delay and even blockage of equipment is avoided;

the top plate 22 is arranged at the top end of the guide mechanism 18, the top ends of the hydraulic rods 3 are respectively connected to the lower surfaces of the left side and the right side of the top plate 22, pneumatic lifting rods 23 are respectively arranged at the left side and the right side below the top plate 22 and close to the vertical central line of the top plate 22, the bottom ends of the pneumatic lifting rods 23 are connected with an upper die movable seat 24, buffer insertion ways 25 are respectively arranged at the left side and the right side of the upper surface of the upper die movable seat 24, one ends of buffer springs 26 are respectively fixed at the inner bottoms of the buffer insertion ways 25, the other ends of the buffer springs 26 are respectively and fixedly connected with buffer guide rods 27, the buffer guide rods 27 are inserted and matched in the buffer insertion ways 25, the top ends of the buffer guide rods 27 are respectively welded and fixed on the lower surface of the top plate 22, a buffer part consisting of the buffer insertion ways 25, the buffer springs 26 and the buffer guide rods 27 has the same specific structure and function as the guide mechanism 18, and the difference is that, the concrete action object of the guide mechanism 18 is the top plate 22, the concrete action object of the buffer part consisting of the buffer insert 25, the buffer spring 26 and the buffer guide rod 27 is the upper die part, the buffer insert 25 and the buffer guide rod 27 are mutually matched, the upper die movable seat 24 can be ensured to stably move up and down, the buffer spring 26 ensures that the upper die movable seat 24 can move up and down with certain recovery performance, after the die is closed, the smooth completion of the die opening action can be facilitated, the buffer part consisting of the buffer insert channel 25, the buffer spring 26 and the buffer guide rod 27 is used as a main guide and reset structure of the upper die, the smooth continuous operation of the die opening and closing action is effectively ensured, the guide mechanism 18 is used as an auxiliary guide and reset structure of the upper die, so that the problems of guide deviation or untimely die separation caused by abrasion after the production equipment is used for a long time are directly and effectively solved;

an upper die base 28 is fixed below the upper die movable seat 24, a plate passing groove 29 is arranged below the upper die base 28, the push plate mechanisms 30 are respectively arranged on the front side and the rear side of the upper die base 28, the push plate mechanisms 30 are composed of pressure pipes 31, rocker arms 33, connecting plates 34, rotating rods 36, mounting sleeves 43 and micro motors 45, the micro motors 45 are fixed on the upper die base 28 through welding plates, the micro motors 45 are symmetrical with each other about the vertical central line of the upper die base 28, the middle parts of the pressure pipes 31 are respectively fixed and hung on the front side and the rear side of the upper die base 28 through the welding plates, bearings 32 are sleeved on the outer sides of the two ends of the pressure pipes 31, the rocker arms 33 are sleeved on the outer sides of the bearings 32, the connecting plates 34 are connected to one side, close to the vertical central line of the pressure pipes 31, of the end parts of the rocker arms 33, the two connecting plates 34 are symmetrically arranged about the vertical central line of the pressure pipes 31, the rotating rods 36 are rotatably connected between the connecting plates 34, the centers of two end surfaces of the rotating rod 36 are respectively fixed with a rotating shaft rod 35, the outer wall surface of the rotating rod 36 is provided with bristles 37 in a cross shape, the rotating shaft rods 35 respectively penetrate through the centers of the connecting plates 34, the end parts of the rotating shaft rods 35 are respectively sleeved with a small transmission disc 38, the outer part of the small transmission disc 38 is respectively sleeved with a transmission belt 39, the other ends of the transmission belts 39 are respectively sleeved with a large transmission disc 40, the middle part of the inner wall of the large transmission disc 40 is respectively fixed with a rotating rod 41, the center of the rotating rod 41 is provided with a ferrule, the center of the rotating rod 41 is sleeved at the output shaft end of the micro motor 45, clamping rings 42 respectively protrude from two side surfaces of the edge of the rotating rod 41, the left side of the rotating rod 41 is provided with a mounting sleeve 43, the end surface of the mounting sleeve 43 close to the rotating rod 41 and the end surface of the pressure pipe 31 close to the rotating rod 41 are respectively provided with a clamping groove 44, and the clamping rings 42 are respectively matched in the clamping grooves 44 in a sliding manner;

by using the bearing 32, not only can the pressure pipe 31 and the rocker 33 be well assembled, but also the rocker 33 can rotate on the basis of the pressure pipe 31, so as to adjust the height positions of the connecting plate 34 and the rotating rod 36, and by raising or lowering the height of the rotating rod 36, plates with different thicknesses can be pushed into a mold, the bristles 37 on the outer wall of the rotating rod 36 can increase friction, so that when the rotating rod 36 rotates, good pushing force can be applied to the plates, and smooth and continuous feeding of the plates can be ensured, the power of the rotating rod 36 comes from the micro motor 45, after the micro motor 45 is started, the rotating rod 41 can be driven to rotate by virtue of the rotation of the output end, the rotating rod 41 and the large transmission disc 40 are fixedly welded integrally, so that the large transmission disc 40 also immediately rotates between the mounting sleeve 43 and the pressure pipe 31, and due to the matching relationship between the snap ring 42 and the snap groove 44, the large transmission disc 40 can rotate relative to the mounting sleeve 43 and the pressure pipe 31, therefore, the large transmission disc 40 can independently drive the transmission belt 39 to move so as to drive the small transmission disc 38 to rotate, the rotating small transmission disc 38 immediately drives the rotating rod 36 to rotate through the rotating shaft rod 35, the rotating rod 36 applies thrust to the plate in the rotating process, the plate is assisted to enter the die quickly, and the produced fin is also output from the die quickly and stably through the structure;

the heat exchange fin production equipment is provided with two guide and buffer structures and two pressing die lifting power structures, namely a hydraulic lifting structure consisting of a hydraulic cylinder 2 and a hydraulic rod 3 and a pneumatic lifting structure consisting of a pneumatic lifting rod 23, wherein, the pneumatic lifting rod 23 is used as the main power part of the upper die part and directly bears the die opening and closing pressure, thereby ensuring that the die opening and closing action can be smoothly and completely carried out, the hydraulic lifting structure consisting of the hydraulic cylinder 2 and the hydraulic rod 3 is used as an auxiliary power part of the upper die part, the direct acting object is the top plate 22, the top plate 22 is driven to ascend and descend, the upper die part is assisted to stably move up and down, good assistance is provided for the up-and-down movement of the upper die part, the problems that the die opening and closing actions of production equipment are not consistent and timely due to aging are avoided, and the service life and the comprehensive using effect of the improved heat exchange fin production equipment are effectively prolonged.

To sum up, when the improved heat exchange fin production equipment is used, a proper lower template 16 is assembled on the air transmission seat 11, a proper upper template is arranged in the upper template base 28, the micro motor 45 is started, the micro motor 45 drives the rotating shaft rod 35 and the rotating rod 36 to rotate by using a transmission structure consisting of the rotating rod 41, the large transmission disc 40, the transmission belt 39 and the small transmission disc 38, the plate can be quickly and stably conveyed between the upper and lower templates by using the bristles 37 on the outer wall of the rotating rod 36 to boost the plate, the pneumatic lifting rod 23 is started, the upper template part moves downwards integrally, the buffer spring 26 is stretched immediately, in order to ensure sufficient power for opening and closing the template, the hydraulic cylinders 2 can be started simultaneously to drive the hydraulic rods 3 to shrink, the guide spring 21 in the guide mechanism 18 shrinks immediately, after the template pressing is completed, under the respective elastic performances of the buffer spring 26 and the guide spring 21 are restored, and the pneumatic lifting rod 23 is shortened, and the hydraulic rods 3 are extended under the combined action, so that the upper die and the lower die are quickly separated, compressed air is quickly input into a compressed pipeline in the air base 4, the compressed air is output through the air transmission hole 5 and then is respectively guided into the air transmission pipeline 14 through the connecting pipe 46, the compressed air passes through the conical air passage 15 and the air through passage 17 which can be communicated, the compressed air rises above the lower die plate 16, the pressed heat exchange fins can be quickly jacked up to be separated from the lower die plate 16 by utilizing air pressure thrust, the unprocessed plate is input between the upper die and the lower die again through the rotary rod 36 which continuously rotates at the front side, the processed fin part is also quickly output from the upper die and the lower die through the rotary rod 36 which continuously rotates at the rear side, and the steps are repeated, so that the continuous fin production can be completed.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (10)

1. The utility model provides an improved generation heat transfer fin production facility, includes support base (1), guiding mechanism (18), roof (22) and push pedal mechanism (30), its characterized in that: the pneumatic lifting device is characterized in that hydraulic cylinders (2) are arranged on the left front side and the right rear side of the supporting base (1), the output ends of the hydraulic cylinders (2) are connected with hydraulic rods (3), an air base (4) is fixed at the center of the upper portion of the supporting base (1), air conveying holes (5) penetrate through the front side face of the air base (4) at equal intervals, a lower die supporting seat (6) is fixed above the air base (4), guide mechanisms (18) are vertically arranged on the left side and the right side of the upper portion of the supporting base (1) respectively, each guide mechanism (18) is composed of a guide pipe (19), a guide rod (20) and a guide spring (21), the top plate (22) is arranged at the top end of each guide mechanism (18), the top ends of the hydraulic rods (3) are connected to the lower surfaces of the left side and the right side of the top plate (22) respectively, pneumatic lifting rods (23) are arranged on the left side and the right side of the lower portion of the top plate (22) and the left side close to the vertical central line of the top plate (22), and the bottom of pneumatic lifter (23) is connected with mould sliding seat (24), the below of going up mould sliding seat (24) is fixed with mould base (28), and the below of going up mould base (28) is provided with board groove (29), both sides around last mould base (28) are settled respectively in push pedal mechanism (30), and push pedal mechanism (30) are by pressing pipe (31), rocking arm (33), connecting plate (34), rotary rod (36), installation cover (43) and micro motor (45) and constitute.

2. The improved heat exchange fin production equipment as claimed in claim 1, wherein: the upper portion of the lower die supporting seat (6) is internally provided with a conveyor belt (7), two ends of a driving shaft of the conveyor belt (7) are connected with transmission motors (9), and rectangular blocks (8) are uniformly and alternately arranged on the belt surface of the conveyor belt (7).

3. The improved heat exchange fin production equipment as claimed in claim 2, wherein: a lower die base plate (10) is arranged above the conveyor belt (7), the bottom surface of the lower die base plate (10) is matched with the rectangular block (8) in size, an air transmission seat (11) is fixed above the lower die base plate (10), and a lower die plate (16) is arranged above the air transmission seat (11) in a matched mode.

4. The improved heat exchange fin production equipment as claimed in claim 3, wherein: the upper surface of gas transmission seat (11) evenly is provided with cooperation groove (12), and the inner bottom of cooperation groove (12) is the rectangle form and all bonds and be fixed with rubber filler strip (13), the inside of gas transmission seat (11) and with cooperation groove (12) relative position department all is provided with gas transmission pipeline (14), and the top of gas transmission pipeline (14) all communicates there is toper air flue (15), the inside of lower bolster (16) evenly runs through and has worn air flue (17), and wears position one-to-one between air flue (17) and toper air flue (15), all be connected with connecting pipe (46) between gas transmission pipeline (14) and gas transmission hole (5).

5. The improved heat exchange fin production equipment as claimed in claim 1, wherein: the bottom of guide tube (19) all welds perpendicularly at the upper surface that supports base (1), and the inside of guide tube (19) is vertical to be run through has guide bar (20), be connected with between the bottom surface of guide bar (20) and the interior bottom surface of guide tube (19) guide spring (21).

6. The improved heat exchange fin production equipment as claimed in claim 1, wherein: go up the upper surface left and right sides of mould sliding seat (24) and all be provided with buffering inserted way (25), and the inside bottom of buffering inserted way (25) all is fixed with the one end of buffer spring (26), other fixedly connected with buffering guide arm (27) are equallyd divide to the other end of buffer spring (26), and buffering guide arm (27) insert the cooperation in buffering inserted way (25) to the equal welded fastening in top of buffering guide arm (27) is on the lower surface of roof (22).

7. The improved heat exchange fin production equipment as claimed in claim 1, wherein: micro motor (45) are fixed on last mould base (28) through the welding plate, and between micro motor (45) about the vertical central line symmetry of last mould base (28), the middle part of pressing the pipe (31) is fixed hoist and mount respectively in last mould base (28) both sides around through the welding plate.

8. The improved heat exchange fin production equipment as claimed in claim 7, wherein: the utility model discloses a pressure pipe, including connecting rod (31), connecting rod (36), connecting rod (35), bearing (32), rocking arm (33) have all been overlapped in the both ends outside of pressing pipe (31), and the outside of bearing (32) has all been cup jointed, the tip of rocking arm (33) leans on one side of pressing the vertical central line of pipe (31) all is connected with connecting plate (34), and connecting plate (34) are provided with two about the vertical central line symmetry of pressing pipe (31), it is connected with rotary rod (36) to rotate between connecting plate (34), and the both ends face center of rotary rod (36) all is fixed with pivot pole (35), the outer wall of pivot pole (36) is the fork form and evenly is provided with brush hair (37), pivot pole (35) are equallyd divide and are run through from the center of connecting plate (34) respectively.

9. The improved heat exchange fin production equipment as claimed in claim 8, wherein: little drive disk (38) has all been cup jointed to the tip of bull stick (35), and the outside of little drive disk (38) all is overlapped and is equipped with driving belt (39), big drive disk (40) have all been cup jointed to another of driving belt (39), and the inner wall middle part of big drive disk (40) all is fixed with bull stick (41), the center of bull stick (41) is equipped with the lasso, and the output axle head at micro motor (45) is cup jointed at the center of bull stick (41).

10. The improved heat exchange fin production equipment as claimed in claim 9, wherein: snap ring (42) have all been outstanding to the edge both sides face of bull stick (41), and the left side of bull stick (41) is provided with installation cover (43), the terminal surface that installation cover (43) are close to bull stick (41) all is provided with draw-in groove (44) with the terminal surface that presses pipe (31) to be close to bull stick (41), and snap ring (42) are equallyd divide and are do not sliding fit in draw-in groove (44).

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