CN221066939U - Carbon fiber badminton racket forming die - Google Patents

Abstract

The utility model discloses a carbon fiber badminton racket forming die in the technical field of forming dies, which comprises a base, wherein the top of the base is provided with a lower die, the top of the lower die is provided with a forming groove, the bottom of a top plate is provided with a hydraulic rod, the bottom of the hydraulic rod is provided with a fixed plate, the inside of the lower die is provided with a cooling cavity, the outer side wall of the lower die is provided with a cooling component, the inside of the lower die is provided with a cavity, the cavity is internally provided with a demoulding mechanism, and the demoulding mechanism comprises a sliding plate which is arranged in the cavity in a sliding connection manner; can carry out the drawing of patterns to fashioned carbon fiber racket under the cooperation of demoulding mechanism, do not need the staff to carry out manual drawing of patterns, reduce because the drawing of patterns causes the problem of carbon fiber racket damage, convenient to use.

Description

Carbon fiber badminton racket forming die

Technical Field

The utility model relates to the technical field of forming dies, in particular to a carbon fiber badminton racket forming die.

Background

The badminton racket is one of very favorite sports, the badminton racket generally comprises a racket head, a racket rod, a racket handle and joints of a racket frame and the racket rod, the development weight of the racket is lighter and lighter, the carbon fiber badminton racket is the first choice of wide badminton lovers, a forming die is required to be used for hot pressing when the carbon fiber badminton racket is manufactured, most of the existing forming die is naturally cooled and then taken out after the carbon fiber badminton racket is formed, the cooling is slow, the working efficiency is affected, the existing carbon fiber badminton racket is required to be manually demoulded after being formed, a worker needs to take out a product from the die by hand, sometimes the carbon fiber badminton racket is adhered to the inner wall of a forming groove, and the worker can possibly damage the carbon fiber badminton racket when taking out the carbon fiber badminton racket forcefully.

Disclosure of utility model

The utility model aims to provide a carbon fiber badminton racket forming die which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a carbon fiber racket forming die, includes the base, and the base top is equipped with four groups support columns, and four groups support column tops are equipped with the roof, the base top is equipped with the bed die, and the shaping groove has been seted up at the bed die top, the roof bottom is equipped with the hydraulic stem, and the hydraulic stem bottom is equipped with the fixed plate, and the fixed plate bottom is equipped with the last mould with bed die assorted, go up mould right side wall and run through the intercommunication and be equipped with the inlet pipe, the cooling chamber has been seted up to the inside cooling chamber of bed die, the bed die lateral wall is equipped with cooling module, the cavity has been seted up to the inside of bed die, is equipped with demoulding mechanism in the cavity, demoulding mechanism includes the sliding plate that sliding connection was equipped with in the cavity, the ejector pin top is equipped with, ejector pin one end runs through the stripper plate that top and shaping inslot was equipped with, the ejector pin outer wall cup joints and is equipped with first spring, and first spring one end is connected with the top in the cavity, and the first spring other end is connected with the sliding plate top, two sets of spouts have been seted up to the cavity inner bottom, equal sliding connection in two sets of spouts are equipped with the slider, and two sets of slider tops all articulate and are equipped with first connecting rod, and first connecting rod one end all articulates with the connecting rod bottom phase-connection, the cavity bottom is articulated, two sets of connecting rod bottom all have two sets of side wall sets of connecting rod, and two side wall are articulated in the inside the cavity, two sets of connecting rod and bottom is articulated.

Further, extrusion subassembly includes the sliding block that bottom sliding connection was equipped with in the cavity, sliding block left side wall is equipped with the extrusion pole, and extrusion pole one end is connected with slider right side wall, the extrusion pole outer wall cup joints and has been equipped with vertical board, and vertical board bottom is connected with the cavity bottom, the extrusion pole outer wall cup joints and has been equipped with the third spring, and third spring one end is connected with vertical board right side wall, the third spring other end is connected with sliding block left side wall, right side wall sliding connection is equipped with the extrusion piece with sliding block assorted in the cavity, and right side wall is equipped with the mounting panel in the cavity, and the mounting panel bottom is equipped with electric telescopic handle, and electric telescopic handle one end is connected with extrusion piece top.

Further, the sliding block and the extrusion block are arranged in a right-angle trapezoid shape.

Further, a placing groove is formed in the bottom in the forming groove, and the stripper plate is matched with the placing groove.

Further, reset assembly includes the sleeve that bottom was equipped with in the cavity, and sliding connection is equipped with the fly leaf in the sleeve, and the fly leaf top is equipped with the movable rod, and movable rod one end runs through the sleeve in top and is connected with the connecting block bottom, the fly leaf bottom is equipped with the second spring, and second spring one end is connected with the sleeve bottom.

Further, the cooling module includes the water pump that the bed die right side wall was equipped with, and water pump play water end connection is equipped with the outlet pipe, and outlet pipe one end is linked together with the cooling chamber inside, water pump water inlet end connection is equipped with the drinking-water pipe, the side wall is equipped with refrigeration plant behind the bed die, and drinking-water pipe one end is connected with refrigeration plant, the side wall is equipped with the radiator behind the refrigeration plant, the bed die left side wall is equipped with the circulating pump, and the circulating pump is connected to be equipped with the inlet tube in the water inlet end, and inlet tube one end is linked together with the cooling chamber inside, circulating pump play water end connection is equipped with the conveyer pipe, and conveyer pipe one end is connected with refrigeration plant.

Compared with the prior art, the utility model has the beneficial effects that: the utility model can cool the carbon fiber badminton racket molded in the molding groove under the cooperation of the cooling component and the cooling cavity, and can improve the cooling speed of the carbon fiber badminton racket, thereby improving the working efficiency; can carry out the drawing of patterns to fashioned carbon fiber racket under the cooperation of demoulding mechanism, do not need the staff to carry out manual drawing of patterns, reduce because the drawing of patterns causes the problem of carbon fiber racket damage, convenient to use.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a top view of the internal structure of the cooling chamber of the present utility model;

FIG. 3 is a schematic view of the internal structure of the cavity of the present utility model;

FIG. 4 is a schematic view of the structure A of the present utility model;

fig. 5 is a schematic diagram of the structure of the present utility model B.

In the figure: 1. a base; 2. a lower die; 3. a support column; 4. a forming groove; 5. an upper die; 6. a feed pipe; 7. a fixing plate; 8. a hydraulic rod; 9. a top plate; 10. a cooling chamber; 11. a cooling assembly; 110. a water outlet pipe; 111. a water pump; 112. a water pumping pipe; 113. a refrigeration device; 114. a heat sink; 115. a delivery tube; 116. a circulation pump; 117. a water inlet pipe; 12. a demoulding mechanism; 120. removing the template; 121. a push rod; 122. a first spring; 123. a first link; 124. a connecting block; 125. a second link; 126. a reset assembly; 1260. a movable rod; 1261. a sleeve; 1262. a movable plate; 1263. a second spring; 127. a chute; 128. a slide block; 129. an extrusion assembly; 1290. an extrusion rod; 1291. a vertical plate; 1292. a third spring; 1293. a sliding block; 1294. extruding a block; 1295. an electric telescopic rod; 1296. a mounting plate; 1200. a sliding plate; 13. a cavity; 14. and (5) placing a groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1:

Referring to fig. 1-3, the present utility model provides a technical solution: the utility model provides a carbon fiber racket forming die, including base 1, base 1 top is equipped with four sets of support columns 3, four sets of support column 3 tops are equipped with roof 9, base 1 top is equipped with bed die 2, shaping groove 4 has been seted up at bed die 2 top, roof 9 bottom is equipped with hydraulic stem 8, hydraulic stem 8 bottom is equipped with fixed plate 7, fixed plate 7 bottom is equipped with the last mould 5 with bed die 2 assorted, upward mould 5 right side wall runs through the intercommunication and is equipped with inlet pipe 6, cooling chamber 10 has been seted up to bed die 2 inside, bed die 2 lateral wall is equipped with cooling module 11, cavity 13 has been seted up to bed die 2 inside, be equipped with demoulding mechanism 12 in the cavity 13, demoulding mechanism 12 includes slip board 1200 that sliding connection was equipped with in cavity 13, slip board 1200 top is equipped with ejector pin 121, ejector pin 121 one end runs through the top in cavity 13 and is connected with stripper plate 120 that is equipped with in shaping groove 4, the inner bottom of the forming groove 4 is provided with a placing groove 14, the stripper plate 120 is matched with the placing groove 14, the stripper plate 120 can be placed in the placing groove 14 when not demolding, the outer wall of the ejector rod 121 is sleeved with a first spring 122, one end of the first spring 122 is connected with the inner top of the cavity 13, the other end of the first spring 122 is connected with the top of the sliding plate 1200, the inner bottom of the cavity 13 is provided with two groups of sliding grooves 127, sliding blocks 128 are arranged in the two groups of sliding grooves 127 in a sliding manner, the tops of the two groups of sliding blocks 128 are hinged with first connecting rods 123, one end of each first connecting rod 123 is hinged with the bottom of the sliding plate 1200, the left side and the right side of the inner bottom of the cavity 13 are both provided with extrusion assemblies 129, the inner side walls of the two groups of the first connecting rods 123 are hinged with second connecting rods 125, a connecting block 124 is arranged below the sliding plate 1200, one end of each second connecting rod 125 is hinged with the left side wall and the right side wall of the connecting block 124 respectively, a reset assembly 126 is provided at the bottom of the cavity 13.

Referring to fig. 5, the extrusion assembly 129 includes a sliding block 1293 slidably connected to the bottom in the cavity 13, an extrusion rod 1290 is disposed on the left side wall of the sliding block 1293, one end of the extrusion rod 1290 is connected to the right side wall of the sliding block 128, a vertical plate 1291 is sleeved on the outer wall of the extrusion rod 1290, the bottom of the vertical plate 1291 is connected to the bottom in the cavity 13, a third spring 1292 is sleeved on the outer wall of the extrusion rod 1290, one end of the third spring 1292 is connected to the right side wall of the vertical plate 1291, the other end of the third spring 1292 is connected to the left side wall of the sliding block 1293, an extrusion block 1294 matched with the sliding block 1293 is slidably connected to the right side wall in the cavity 13, a mounting plate 1296 is disposed on the right side wall in the cavity 13, an electric telescopic rod 1295 is disposed at the bottom of the mounting plate 1296, one end of the electric telescopic rod 1295 is connected to the top of the extrusion block 1294, the sliding block 1293 and the extrusion block 1294 are all in a right trapezoid shape, the electric telescopic rod 1295 is driven to move downward, the extrusion block 1294 is inclined plane, the sliding block 1293 can extrude the sliding block 1293 and the sliding block 1290, and the sliding block 1290 can move the sliding block 128.

Referring to fig. 4, the reset assembly 126 includes a sleeve 1261 disposed at the bottom of the cavity 13, a movable plate 1262 is slidably disposed in the sleeve 1261, a movable rod 1260 is disposed at the top of the movable plate 1262, one end of the movable rod 1260 penetrates through the inner top of the sleeve 1261 to be connected with the bottom of the connecting block 124, a second spring 1263 is disposed at the bottom of the movable plate 1262, and one end of the second spring 1263 is connected with the inner bottom of the sleeve 1261.

Referring to fig. 2, the cooling assembly 11 includes a water pump 111 disposed on a right side wall of the lower mold 2, a water outlet pipe 110 is connected to a water outlet end of the water pump 111, one end of the water outlet pipe 110 is connected to an inside of the cooling cavity 10, a water suction pipe 112 is connected to a water inlet end of the water pump 111, a refrigerating device 113 is disposed on a rear side wall of the lower mold 2, one end of the water suction pipe 112 is connected to the refrigerating device 113, a radiator 114 is disposed on a rear side wall of the refrigerating device 113, a circulating pump 116 is disposed on a left side wall of the lower mold 2, a water inlet end of the circulating pump 116 is connected to a water inlet pipe 117, one end of the water inlet pipe 117 is connected to the inside of the cooling cavity 10, a conveying pipe 115 is connected to a water outlet end of the circulating pump 116, and one end of the conveying pipe 115 is connected to the refrigerating device 113.

Working principle: the fixing plate 7 is driven to move downwards under the action of the hydraulic rod 8, the fixing plate 7 drives the upper die 5 to move downwards to be matched with the lower die 2, then carbon fiber materials enter the forming groove 4 from the feeding pipe 6 for hot press forming, after forming is finished, the hydraulic rod 8 drives the upper die 5 to be separated from the lower die 2, then the water pump 111 drives cold water in the refrigerating equipment 113 to enter the cooling cavity 10 through the water suction pipe 112 and the water outlet pipe 110, then the cold water in the cooling cavity 10 can cool the carbon fiber badminton racket in the forming groove 4, then the circulating pump 116 can convey water in the cooling cavity 10 to the refrigerating equipment 113 through the conveying pipe 115 for cooling, the carbon fiber materials can be recycled, the heat generated by cooling of the refrigerating equipment 113 can be emitted, the cooled carbon fiber feathers need to be demoulded, the extruding block 1294 is driven to move downwards under the action of the electric telescopic rod 1295, the inclined surface of the extrusion block 1294 can extrude the inclined surface of the sliding block 1293, the sliding block 1293 can extrude the extrusion rod 1290 and the third spring 1292, the extrusion rod 1290 can drive the sliding block 128 to move, the sliding block 128 drives the first connecting rod 123 to rotate, the second connecting rod 125 is driven to rotate when the first connecting rod 123 rotates, the second connecting rod 125 drives the connecting block 124 to move downwards, the connecting block 124 drives the movable rod 1260 to move downwards, the movable plate 1262 is driven to move downwards to extrude the second spring 1263, the sliding plate 1200 is driven to move upwards when the first connecting rod 123 rotates, the sliding plate 1200 drives the ejector rod 121 to move upwards, meanwhile, the sliding plate 1200 can extrude the first spring 122, the ejector rod 121 drives the stripper plate 120 to move upwards (the stripper plate 120 is positioned at the joint of the racket frame and the racket rod), the demoulding plate 120 can demould the formed carbon fiber badminton racket, and is convenient to use.

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

Claims (6)

1. The utility model provides a carbon fiber racket forming die, includes base (1), and base (1) top is equipped with four sets of support columns (3), and four sets of support columns (3) tops are equipped with roof (9), base (1) top is equipped with bed die (2), and shaping groove (4) have been seted up at bed die (2) top, roof (9) bottom is equipped with hydraulic stem (8), and hydraulic stem (8) bottom is equipped with fixed plate (7), and fixed plate (7) bottom is equipped with mould (5) on with bed die (2) assorted, go up mould (5) right side wall and run through the intercommunication and be equipped with inlet pipe (6), its characterized in that: the cooling cavity (10) is formed in the lower die (2), the cooling component (11) is arranged on the outer side wall of the lower die (2), the cavity (13) is formed in the lower die (2), the demoulding mechanism (12) is arranged in the cavity (13), the demoulding mechanism (12) comprises a sliding plate (1200) which is arranged in the cavity (13) in a sliding mode, the top of the sliding plate (1200) is provided with a push rod (121), one end of the push rod (121) penetrates through the inner top of the cavity (13) and is connected with a demoulding plate (120) which is arranged in a forming groove (4), a first spring (122) is sleeved on the outer wall of the push rod (121), one end of the first spring (122) is connected with the inner top of the cavity (13), the other end of the first spring (122) is connected with the top of the sliding plate (1200), two groups of sliding grooves (127) are formed in the inner bottoms of the cavity (13), sliding blocks (128) are all hinged with first connecting rods (123) in a sliding mode, one end of each connecting rod (123) is hinged with the bottom of the sliding plate (13), two groups of the two inner side walls of the first connecting rods (123) are all hinged with the bottom of the sliding plate (1200), each connecting rod (125), the connecting block (124) is arranged below the sliding plate (1200), one ends of the two groups of second connecting rods (125) are respectively hinged with the left side wall and the right side wall of the connecting block (124), and a reset component (126) is arranged at the inner bottom of the cavity (13).

2. The carbon fiber badminton racket molding die of claim 1, wherein: the extrusion assembly (129) comprises a sliding block (1293) arranged in the cavity (13) in a sliding mode, an extrusion rod (1290) is arranged on the left side wall of the sliding block (1293), one end of the extrusion rod (1290) is connected with the right side wall of the sliding block (128), a vertical plate (1291) is sleeved on the outer wall of the extrusion rod (1290), a third spring (1292) is sleeved on the outer wall of the extrusion rod (1290), one end of the third spring (1292) is connected with the right side wall of the vertical plate (1291), the other end of the third spring (1292) is connected with the left side wall of the sliding block (1293), an extrusion block (1294) matched with the sliding block (1293) is arranged on the right side wall in the cavity (13), a mounting plate (1296) is arranged on the inner right side wall of the cavity (13), an electric telescopic rod (1295) is arranged at the bottom of the mounting plate (1296), and one end of the electric telescopic rod (1295) is connected with the top of the extrusion block (1294).

3. The carbon fiber badminton racket molding die of claim 2, wherein: the sliding block (1293) and the extrusion block (1294) are arranged in a right-angle trapezoid shape.

4. The carbon fiber badminton racket molding die of claim 1, wherein: a placing groove (14) is formed in the inner bottom of the forming groove (4), and the stripper plate (120) is matched with the placing groove (14).

5. The carbon fiber badminton racket molding die of claim 1, wherein: the reset assembly (126) comprises a sleeve (1261) arranged at the bottom in the cavity (13), a movable plate (1262) is arranged in sliding connection in the sleeve (1261), a movable rod (1260) is arranged at the top of the movable plate (1262), one end of the movable rod (1260) penetrates through the inner top of the sleeve (1261) and is connected with the bottom of the connecting block (124), a second spring (1263) is arranged at the bottom of the movable plate (1262), and one end of the second spring (1263) is connected with the bottom in the sleeve (1261).

6. The carbon fiber badminton racket molding die of claim 1, wherein: the cooling module (11) comprises a water pump (111) arranged on the right side wall of the lower die (2), a water outlet pipe (110) is connected to the water outlet end of the water pump (111), one end of the water outlet pipe (110) is communicated with the inside of the cooling cavity (10), a water suction pipe (112) is connected to the water inlet end of the water pump (111), refrigerating equipment (113) is arranged on the rear side wall of the lower die (2), one end of the water suction pipe (112) is connected with the refrigerating equipment (113), a radiator (114) is arranged on the rear side wall of the refrigerating equipment (113), a circulating pump (116) is arranged on the left side wall of the lower die (2), a water inlet pipe (117) is connected to the water inlet end of the circulating pump (116), one end of the water inlet pipe (117) is communicated with the inside of the cooling cavity (10), a conveying pipe (115) is connected to the water outlet end of the circulating pump (116), and one end of the conveying pipe (115) is connected with the refrigerating equipment (113).