CN213033540U - Rapid cooling forging die for machining wind power ring - Google Patents
Rapid cooling forging die for machining wind power ring Download PDFInfo
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- CN213033540U CN213033540U CN202021908013.6U CN202021908013U CN213033540U CN 213033540 U CN213033540 U CN 213033540U CN 202021908013 U CN202021908013 U CN 202021908013U CN 213033540 U CN213033540 U CN 213033540U
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Abstract
The utility model discloses a wind-powered electricity generation ring processing is with cooling down forging mould fast, comprising a base plate, the upper end installation die holder of bottom plate, die holder upper cover dress cope match-plate pattern, the upper surface of die holder sets up annular A to annular A's middle part sets up the round hole, the upper surface of cope match-plate pattern sets up annular B to in annular B's the bottom embedding annular A, both ends in the die holder set up water intake pipe and outlet pipe way, and the middle part in the die holder sets up heat transfer pipeline. This wind-powered electricity generation ring processing is with cooling forging mould fast, the cold water through in the pipeline flows and carries out the heat exchange with the heat that wind-powered electricity generation ring released to realize the quick cooling after the wind-powered electricity generation ring forges the shaping, owing to need not to take out the wind-powered electricity generation ring that forges the shaping from the mould, operating procedure such as cooling in cold water submergence again, therefore improved cooling efficiency, labour saving and time saving greatly.
Description
Technical Field
The utility model relates to a wind-powered electricity generation ring forges mould technical field, specifically is a wind-powered electricity generation ring processing is with cooling down forging mould fast.
Background
The wind power ring is one of important parts of the wind driven generator and is mostly formed by alloy forging; the forging die is used in the forging process and has the following principle: the raw material is plastically deformed in the forging die by an external force, thereby obtaining a part of a desired shape and size.
After the wind power ring is formed in the forging die, the wind power ring can have extremely high heat, and the traditional forging die does not have a quick cooling function, so that the wind power ring needs to be immersed in cold water for a long time for cooling after being forged, and is very inconvenient, time-consuming and labor-consuming.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a wind-powered electricity generation ring processing is with cooling fast forging mould, the heat that flows and wind-powered electricity generation ring release through the cold water in the pipeline carries out the heat exchange to realize the quick cooling after the wind-powered electricity generation ring forges the shaping, owing to need not to take out the fashioned wind-powered electricity generation ring of forging from the mould, operating procedure such as cooling in cold water submergence again, therefore improved cooling efficiency, labour saving and time saving greatly, can solve the problem among the prior art.
In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a wind-powered electricity generation ring processing is with cooling fast forging mould, includes the bottom plate, the upper end installation die holder of bottom plate, die holder upper cover dress cope match-plate pattern, the upper surface of die holder sets up annular A to annular A's middle part sets up the round hole, the upper surface of cope match-plate pattern sets up annular B to in annular B's the bottom embedding annular A, both ends in the die holder set up water intake pipe and outlet conduit, and the middle part in the die holder sets up heat transfer pipeline.
Preferably, the water inlet pipeline comprises a pipe plate A, a water pipe and a water inlet pipe orifice, the pipe plate A is installed at one end in the lower die base in parallel, the water pipe is wound on the pipe plate A and fixed through a pipe clamp, the water inlet pipe orifice is installed on the outer side wall of the lower die base, and one end of the water inlet pipe orifice penetrates through the side wall of the lower die base, extends into the die and is connected with one end of the water pipe.
Preferably, the water outlet pipeline comprises a tube plate B, a drain pipe and a drain pipe opening, the tube plate B is arranged at the other end in the lower die base in parallel, the drain pipe is coiled on the tube plate B and fixed through a pipe clamp, the drain pipe opening is arranged on the outer side wall of the lower die base, and one end of the drain pipe opening penetrates through the side wall of the lower die base, extends into the die and is connected with one end of the drain pipe.
Preferably, the heat exchange pipeline includes tube socket and spiral pipe, the tube socket is installed in the middle part in the die holder to the upper surface of tube socket sets up the circular slot, the one end gomphosis of spiral pipe is installed in the circular slot, and the other end of spiral pipe inserts in the circular hole to laminate mutually with the inboard wall of circular hole, the tube mouth end of spiral pipe respectively with raceway, drain pipe connection.
Preferably, the pipe clamp comprises a substrate, an arc block and an arc groove, the substrate is uniformly arranged on the pipe plate A and the pipe plate B, the arc block is installed on the substrate, the arc groove is formed in the end face of the arc block, the notch of the arc groove is matched with the water delivery pipe and the water discharge pipe, and the pipe body of the water delivery pipe and the water discharge pipe is embedded into the notch of the arc groove to be fixed.
Compared with the prior art, the beneficial effects of the utility model are as follows:
the rapidly-cooled forging die for processing the wind power ring is characterized in that after the wind power ring formed by forging is placed in a ring groove B formed in an upper die plate with the same size as the wind power ring, cold water is input through a water inlet pipe orifice formed in a lower die base and is conveyed into a heat exchange pipeline through a water conveying pipe, the cold water can climb along the path of a spiral pipe in the process of flowing in the heat exchange pipeline, and the cold water can continuously absorb heat released by the wind power ring in the climbing process, so that the wind power ring can be rapidly cooled, and the temperature of the wind power ring can be rapidly reduced until the wind power ring is cooled; and the high temperature hot water of heat transfer then can follow behind the spiral pipe inflow drain pipe to discharge high temperature hot water through the drain pipe mouth that sets up on the die holder, here toward reciprocating, the cold water through in the pipeline flows and carries out the heat exchange with the heat of wind-powered electricity generation ring release, with the quick cooling after realizing the wind-powered electricity generation ring forging shaping, owing to need not to take out the wind-powered electricity generation ring that forges the shaping from the mould, operating procedure such as submergence is cooled in cold water again, therefore improved cooling efficiency, labour saving and time saving greatly.
Drawings
FIG. 1 is an overall structure diagram of the present invention;
FIG. 2 is a structural view of the lower die holder of the present invention;
FIG. 3 is a structural view of the water outlet/drainage pipeline of the present invention;
FIG. 4 is a structural diagram of a heat exchange pipeline of the present invention;
fig. 5 is a structure view of the pipe clamp of the present invention.
In the figure: 1. a base plate; 2. a lower die holder; 21. a ring groove A; 22. a circular hole; 3. mounting a template; 31. a ring groove B; 4. a water inlet pipeline; 41. a tube plate A; 42. a water delivery pipe; 43. a water inlet pipe orifice; 5. a water outlet pipeline; 51. a tube plate B; 52. a drain pipe; 53. a drain pipe orifice; 6. a heat exchange line; 61. a tube holder; 611. a circular groove; 62. a spiral tube; 7. a pipe clamp; 71. a substrate; 72. an arc block; 73. an arc groove.
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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-5, a fast cooling forging die for processing a wind power ring comprises a bottom plate 1, a lower die holder 2 is mounted at the upper end of the bottom plate 1, an upper die plate 3 is mounted on the lower die holder 2 in a covering manner, a ring groove a21 is formed in the upper surface of the lower die holder 2, a round hole 22 is formed in the middle of a ring groove a21, a ring groove B31 is formed in the upper surface of the upper die plate 3, the bottom of the ring groove B31 is embedded into the ring groove a21, a water inlet pipeline 4 and a water outlet pipeline 5 are arranged at two ends in the lower die holder 2, and a heat exchange pipeline 6 is arranged in the middle in; be used for the fashioned wind-powered electricity generation ring of splendid attire with the size forging through annular B31, utilize water inlet pipe 4 with in the water input heat transfer pipeline 6, thereby through the heat exchange that flows of cold water in heat transfer pipeline 6 and wind-powered electricity generation ring release, the purpose to the wind-powered electricity generation ring cooling has been reached, and the high temperature hot water of heat transfer then discharges through outlet pipe way 5, here is reciprocating, the cold water that flows through in the pipeline flows and carries out the heat exchange with the heat of wind-powered electricity generation ring release, realize the quick cooling after the wind-powered electricity generation ring forging shaping.
The water inlet pipeline 4 comprises a tube plate A41, a water delivery pipe 42 and a water inlet pipe opening 43, wherein the tube plate A41 is installed at one end in the lower die base 2 in parallel, the water delivery pipe 42 is wound on the tube plate A41 and fixed through a pipe clamp 7, the water inlet pipe opening 43 is installed on the outer side wall of the lower die base 2, and one end of the water inlet pipe opening 43 penetrates through the side wall of the lower die base 2 and extends into the die and is connected with one end of the water delivery pipe 42.
The water outlet pipeline 5 comprises a tube plate B51, a drain pipe 52 and a drain pipe opening 53, wherein the tube plate B51 is installed at the other end in the lower die base 2 in parallel, the drain pipe 52 is coiled on the tube plate B51 and fixed through a pipe clamp 7, the drain pipe opening 53 is installed on the outer side wall of the lower die base 2, and one end of the drain pipe opening 53 penetrates through the side wall of the lower die base 2 and extends into the die and is connected with one end of the drain pipe 52.
The heat exchange pipeline 6 comprises a pipe seat 61 and a spiral pipe 62, wherein the pipe seat 61 is installed in the middle of the lower die seat 2, a round groove 611 is formed in the upper surface of the pipe seat 61, one end of the spiral pipe 62 is installed in the round groove 611 in an embedded mode, the other end of the spiral pipe 62 is inserted into the round hole 22 and attached to the inner side wall of the round hole 22, and the pipe orifice end of the spiral pipe 62 is connected with the water conveying pipe 42 and the water discharging pipe 52 respectively.
Cold water is input through the water inlet pipe mouth 43 and is conveyed into the heat exchange pipeline 6 through the water conveying pipe 42, in the process that the cold water flows in the heat exchange pipeline 6, the cold water can climb along the path of the spiral pipe 62, and in the climbing process, the cold water can continuously absorb heat released by the wind power ring, so that the wind power ring can be rapidly cooled, and the temperature of the wind power ring can be rapidly reduced until the wind power ring is cooled; the heat-exchanged high-temperature hot water flows into the water discharge pipe 52 from the coil 62, and is discharged through the water discharge pipe port 53.
The pipe clamp 7 comprises a base plate 71, an arc block 72 and an arc groove 73, wherein the base plate 71 is uniformly arranged on the pipe plate A41 and the pipe plate B51, the arc block 72 is installed on the base plate 71, the arc groove 73 is arranged on the end surface of the arc block 72, the notch of the arc groove 73 is matched with the water conveying pipe 42 and the water drainage pipe 52, and the pipe bodies of the water conveying pipe 42 and the water drainage pipe 52 are embedded into the notch of the arc groove 73 for fixation; the mode of fixing the water pipe 42 and the water discharge pipe 52 through the pipe clamp 7 is simple and convenient to disassemble and assemble, and is convenient for later maintenance and replacement of pipelines.
This wind-powered electricity generation ring processing is with forging mould of cooling fast will forge fashioned wind-powered electricity generation ring and arrange the annular B31 back that sets up rather than the cope match-plate pattern 3 of equidimension in, through the water inlet pipe mouth 43 that sets up on die holder 2 with cold water input to carry to heat exchange pipeline 6 in through raceway 42.
And cold water can climb along the path of the spiral pipe 62 in the process that cold water flows in the heat exchange pipeline 6, and on the way of climbing, cold water can continuously absorb the heat released by the wind power ring, so that the wind power ring can be rapidly cooled, and the temperature of the wind power ring can be rapidly reduced until the wind power ring is cooled.
And the high temperature hot water of heat transfer then can follow spiral pipe 62 and flow in behind the drain pipe 52 to discharge high temperature hot water through the drain pipe mouth 53 that sets up on the die holder 2, here toward reciprocating, the cold water through in the pipeline flows and carries out the heat exchange with the heat of wind-powered electricity generation ring release, realizes the quick cooling after the wind-powered electricity generation ring forging shaping, owing to need not to take out the wind-powered electricity generation ring that forges the shaping from the mould, operating procedure such as cooling in cold water again submergence, therefore improved cooling efficiency, labour saving and time saving greatly.
In summary, the following steps: according to the rapidly-cooled forging die for processing the wind power ring, the ring groove B31 formed in the upper die plate 3 is used for containing the forged and formed wind power ring, cold water can be input into the heat exchange pipeline 6 through the water inlet pipeline 4 through the arranged water inlet pipeline 4, the water outlet pipeline 5 and the heat exchange pipeline 6, the cold water flows in the heat exchange pipeline 6 and then exchanges heat with heat released by the wind power ring, the purpose of cooling the wind power ring is achieved, and high-temperature hot water after heat exchange is discharged through the water outlet pipeline 5 and is continuously circulated; therefore, the wind power ring can be effectively and quickly cooled through the mold, and compared with the traditional operation procedures of taking the wind power ring out of the mold and cooling the wind power ring by immersing the wind power ring in cold water, the cooling efficiency can be greatly improved, the time and the labor are saved, and the prior art problem is effectively solved.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
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.
Claims (5)
1. The utility model provides a wind-powered electricity generation ring processing is with cooling down forging mould fast, includes bottom plate (1), its characterized in that: the upper end installation die holder (2) of bottom plate (1), die holder (2) upper cover dress cope match-plate pattern (3), the upper surface of die holder (2) sets up annular A (21) to the middle part of annular A (21) sets up round hole (22), the upper surface of cope match-plate pattern (3) sets up annular B (31) to in the bottom embedding annular A (21) of annular B (31), both ends in die holder (2) set up inlet channel (4) and outlet conduit (5), and the middle part in die holder (2) sets up heat transfer pipeline (6).
2. The rapidly-cooled forging die for machining the wind power ring as claimed in claim 1, wherein the rapidly-cooled forging die comprises: the water inlet pipeline (4) comprises a pipe plate A (41), a water conveying pipe (42) and a water inlet pipe orifice (43), the pipe plate A (41) is installed at one end of the lower die holder (2) in parallel, the water conveying pipe (42) is wound on the pipe plate A (41) and fixed through a pipe clamp (7), the water inlet pipe orifice (43) is installed on the outer side wall of the lower die holder (2), and one end of the water inlet pipe orifice (43) penetrates through the side wall of the lower die holder (2) to extend into the die and is connected with one end of the water conveying pipe (42).
3. The rapidly-cooled forging die for machining the wind power ring as claimed in claim 1, wherein the rapidly-cooled forging die comprises: outlet pipe way (5) include tube sheet B (51), drain pipe (52) and drain pipe mouth (53), the other end in lower die holder (2) is installed in parallel to tube sheet B (51), drain pipe (52) coil on tube sheet B (51) to it is fixed through pipe clamp (7), drain pipe mouth (53) are installed on the lateral wall of lower die holder (2) to the lateral wall that lower die holder (2) was run through to the one end of drain pipe mouth (53) extends to the mould in, and is connected with the one end of drain pipe (52).
4. The rapidly-cooled forging die for machining the wind power ring as claimed in claim 1, wherein the rapidly-cooled forging die comprises: heat exchange tube way (6) include tube socket (61) and spiral pipe (62), tube socket (61) are installed in the middle part in lower die holder (2) to the upper surface of tube socket (61) sets up circular slot (611), the one end gomphosis of spiral pipe (62) is installed in circular slot (611), and the other end of spiral pipe (62) inserts in round hole (22) to laminate mutually with the inboard wall of round hole (22), the tube mouth end of spiral pipe (62) is connected with raceway (42), drain pipe (52) respectively.
5. The rapidly-cooled forging die for machining the wind power ring as claimed in claim 3, wherein the rapidly-cooled forging die comprises: the pipe clamp (7) comprises a base plate (71), arc blocks (72) and arc grooves (73), wherein the base plate (71) is uniformly arranged on the pipe plate A (41) and the pipe plate B (51), the arc blocks (72) are installed on the base plate (71), the arc grooves (73) are formed in the end face of the arc blocks (72), the notches of the arc grooves (73) are matched with the water conveying pipe (42) and the water discharging pipe (52), and the water conveying pipe (42) and the water discharging pipe (52) are embedded into the notches of the arc grooves (73) to be fixed.
Priority Applications (1)
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CN202021908013.6U CN213033540U (en) | 2020-09-03 | 2020-09-03 | Rapid cooling forging die for machining wind power ring |
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CN202021908013.6U CN213033540U (en) | 2020-09-03 | 2020-09-03 | Rapid cooling forging die for machining wind power ring |
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CN213033540U true CN213033540U (en) | 2021-04-23 |
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CN202021908013.6U Active CN213033540U (en) | 2020-09-03 | 2020-09-03 | Rapid cooling forging die for machining wind power ring |
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