CN222628536U - Plastic mould for high-precision product production and processing - Google Patents

Abstract

The utility model discloses a plastic mold for producing and processing high-precision products, which belongs to the technical field of plastic molds and comprises a device bottom plate, wherein a mold base is fixedly connected to the right center of the top end of the device bottom plate, a molding cavity is formed in the top end of the mold base, positioning blocks are fixedly connected to the periphery of the top end of the mold base, an ejection assembly and a cooling assembly are arranged in the mold base, supporting rods are fixedly connected to the left side and the right side of the top end of the device bottom plate, a telescopic rod is connected to the top end of the supporting rods in a sliding manner, a mold top plate is fixedly connected to the top end of the telescopic rod, a positioning groove is formed in the bottom end of the mold top plate, the positioning groove is mutually clamped with the positioning blocks, two pouring ports are formed in the right side of the top end of the mold top plate, and a constant temperature box is fixedly connected to the right center of the top end of the mold top plate.

Description

Plastic mould for high-precision product production and processing

Technical Field

The utility model belongs to the technical field of plastic molds, and particularly relates to a plastic mold for producing and processing high-precision products.

Background

A plastic mold is a short term for a combination mold for compression molding, extrusion molding, injection, blow molding, and low foaming molding. The coordination change of the male die, the female die and the auxiliary forming system can process a series of plastic parts with different shapes and different sizes, and injection molding is a method for producing and modeling industrial products. Products are generally molded using rubber and plastic. Injection molding is a processing method used in mass production of parts having complicated shapes, and specifically, injection molding is a method in which a molten plastic is injected into a cavity by an injection molding machine under high pressure, and after cooling and solidification, a molded article is obtained, and the structure of the mold is uniform although it may vary widely depending on the type and performance of the plastic, the shape and structure of the plastic article, the type of the injection machine, and the like.

The utility model provides a high-precision product production and processing plastic mould that among the prior art patent bulletin number is CN217777641U, includes the bottom plate, the surface mounting of bottom plate has the lower mould, positioning mechanism is installed to one side of lower mould, fixed orifices have been seted up to lower mould, last mould and panel inside, the surface of panel is provided with stop gear, surface one side of lower mould is provided with installation mechanism.

However, the efficiency of the plastic mold is too low when the plastic mold is manufactured, so that a plastic mold for manufacturing and processing a high-precision product is needed, and the problems in the prior art are solved.

Disclosure of utility model

The utility model aims to provide a plastic mold for producing and processing high-precision products, which solves the problems in the prior art.

In order to achieve the above purpose, the plastic mold for producing and processing high-precision products comprises a device bottom plate, wherein a mold base is fixedly connected to the right center of the top end of the device bottom plate, a molding cavity is formed in the top end of the mold base, positioning blocks are fixedly connected to the periphery of the top end of the mold base, an ejection assembly and a cooling assembly are arranged in the mold base, supporting rods are fixedly connected to the left side and the right side of the top end of the device bottom plate, telescopic rods are connected to the top ends of the supporting rods in a sliding mode, a mold top plate is fixedly connected to the top end of the telescopic rods, a positioning groove is formed in the bottom end of the mold top plate, the positioning groove is clamped with the positioning blocks, and two pouring openings are formed in the right side of the top end of the mold top plate.

As a preferred implementation mode, the right center of the top end of the die top plate is fixedly connected with a thermostat, a heating device is arranged on the left side of the thermostat, a plurality of thermostat pipes which are in rectangular arrays are arranged in the side wall of the thermostat, a heating pipe is fixedly connected to the left side of the thermostat pipe, and the left side of the bottom end of the heating pipe is fixedly connected with the heating device.

As a preferred implementation mode, the filling opening has been seted up to the top upper left corner of thermostated container, the bottom surface cover of filling opening is equipped with the shield, two connecting rods of top fixedly connected with of shield, the top fixedly connected with of connecting rod carries the handle, the right side of thermostated container is than bottom fixedly connected with ingress pipe, the right side fixedly connected with force (forcing) pump of ingress pipe, both sides fixedly connected with delivery tube around the force (forcing) pump, the top fixedly connected with pouring tube of delivery tube, the bottom of pouring tube is in the top setting of pouring opening.

As a preferred implementation mode, the ejection assembly comprises two support columns, wherein the two support columns are positioned at the bottom ends of the forming cavity and are symmetrically arranged, the top ends of the two support columns are connected with telescopic columns in a sliding mode, the top ends of the telescopic columns are fixedly connected with ejection plates, and the ejection plates are positioned in the forming cavity and slide up and down.

As a preferred implementation mode, the cooling assembly comprises a cooling tank, the cooling tank is located the inside bottom of mould base, be provided with the cooling water in the cooling tank, the inside left side of cooling tank is provided with the water pump, the top of water pump is provided with water inlet pipe and raceway, the raceway is in the right side setting of water inlet pipe, the top fixedly connected with heat pipe of raceway, the heat pipe is in the bottom setting of shaping cavity, the right side bottom fixedly connected with outlet pipe of heat pipe, the bottom of heat pipe is in the inside setting of cooling tank.

Compared with the prior art, the utility model has the advantages that:

1. Through cooling module, make the plastic mould pouring of pouring in the shaping cavity finish to start the cooling water that the suction pump made in the cooling tank gets into through going into the water pipe, thereby take the cooling water to the heat pipe in through the raceway, thereby flow back to in the cooling tank through the outlet pipe, thereby in the in-process that the cooling water carried because the heat pipe pastes in the bottom of shaping cavity, thereby carry out quick heat absorption to the plastic mould that the pouring was accomplished in the shaping cavity, thereby make the plastic mould quick cooling solidify the shaping, thereby make the device improve fashioned efficiency to the pouring of plastic mould, thereby improved the production efficiency of the device.

2. After cooling, solidifying and forming the plastic mould in the forming cavity through the ejection assembly, driving the telescopic column to slide upwards through the support column, driving the ejector plate to slide upwards through the telescopic column, and enabling the ejector plate to eject the plastic mould base of solidifying and forming in the forming cavity, so that manual operation is saved, and the production efficiency of the device is further improved.

Drawings

Figure 1 is a schematic diagram of the overall structure of the present utility model,

Figure 2 is a schematic elevational view of the present utility model,

Figure 3 is a schematic view of the internal structure of the die base of the utility model,

Fig. 4 is a schematic view of the internal structure of the incubator according to the present utility model.

In the figure, 1, a device bottom plate, 2, a mould base, 3, a support rod, 4, a telescopic rod, 5, a mould top plate, 6, a forming cavity, 7, a positioning block, 8, a positioning groove, 9, a constant temperature box, 10, a heating device, 11, a constant temperature pipe, 12, an injection port, 13, a dust cover, 14, a connecting rod, 15, a lifting handle, 16, an ingress pipe, 17, a booster pump, 18, an eduction pipe, 19, an ejector assembly, 1901, a support column, 1902, a telescopic column, 1903, an ejector plate, 20, a cooling assembly, 2001, a cooling groove, 2002, a water pump, 2003, a water inlet pipe, 2004, a water pipe, 2005, a heat conducting pipe, 2006, a water outlet pipe, 2007, cooling water, 21, a pouring pipe, 22, a pouring port, 23 and a heating pipe are shown.

Detailed Description

The utility model is further described below with reference to examples.

Referring to fig. 1-4, the utility model provides a plastic mold for producing and processing high-precision products, which comprises a device bottom plate 1, wherein a mold base 2 is fixedly connected to the right center of the top end of the device bottom plate 1, a molding cavity 6 is formed in the top end of the mold base 2, positioning blocks 7 are fixedly connected to the periphery of the top end of the mold base 2, an ejection assembly 19 and a cooling assembly 20 are arranged in the mold base 2, support rods 3 are fixedly connected to the left side and the right side of the top end of the device bottom plate 1, the top ends of the support rods 3 are slidably connected with telescopic rods 4, a mold top plate 5 is fixedly connected to the top end of the telescopic rods 4, a positioning groove 8 is formed in the bottom end of the mold top plate 5, the positioning groove 8 is mutually clamped with the positioning blocks 7, and two pouring openings 22 are formed in the right side of the top end of the mold top plate 5.

Further, as shown in fig. 1 and fig. 4, it is worth specifically explaining that the center of the top end of the mold top plate 5 is fixedly connected with a thermostat 9, a heating device 10 is arranged on the left side of the thermostat 9, a plurality of thermostat pipes 11 in a rectangular array are arranged in the side wall of the thermostat 9, a heating pipe 23 is fixedly connected to the left side of the thermostat pipe 11, and the left side of the bottom end of the heating pipe 23 is fixedly connected with the heating device 10.

Further, as shown in fig. 1, fig. 2, fig. 3 and fig. 4, it is worth specifically explaining that the top left upper corner of the incubator 9 is provided with the filling opening 12, the bottom surface cover of the filling opening 12 is provided with the dust cover 13, the top fixedly connected with two connecting rods 14 of the dust cover 13, the top fixedly connected with of the connecting rods 14 carries the handle 15, the right side of the incubator 9 is than the bottom fixedly connected with ingress pipe 16, the right side fixedly connected with force (forcing) pump 17 of ingress pipe 16, the front and back both sides fixedly connected with delivery tube 18 of force (forcing) pump 17, the top fixedly connected with pouring tube 21 of delivery tube 18, the bottom of pouring tube 21 is in the top setting of pouring opening 22.

As further shown in fig. 1, 2 and 4, it is worth specifically describing that the ejector assembly 19 includes two support columns 1901, the two support columns 1901 are located at the bottom ends of the molding cavity 6 and are symmetrically arranged, the top ends of the two support columns 1901 are slidably connected with telescopic columns 1902, the top ends of the telescopic columns 1902 are fixedly connected with ejector plates 1903, and the ejector plates 1903 are located inside the molding cavity 6 and slide up and down.

Further, as shown in fig. 1, 2, 3 and 4, it is worth specifically describing that the cooling assembly 20 includes a cooling tank 2001, the cooling tank 2001 is located at the bottom end of the inside of the mold base 2, cooling water 2007 is provided in the cooling tank 2001, a water pump 2002 is provided at the left side of the inside of the cooling tank 2001, a water inlet pipe 2003 and a water pipe 2004 are provided at the top end of the water pump 2002, the water pipe 2004 is located at the right side of the water inlet pipe 2003, a heat conducting pipe 2005 is fixedly connected at the top end of the water pipe 2004, the heat conducting pipe 2005 is located at the bottom end of the molding cavity 6, a water outlet pipe 2006 is fixedly connected at the right side bottom end of the heat conducting pipe 2005, and the bottom end of the heat conducting pipe 2005 is located inside of the cooling tank 2001.

The scheme comprises the following working processes that pouring liquid is poured into an injection port 12, so that a heating device 10 is started to transfer heat to a constant temperature pipe 11 through a heating pipe 23, the constant temperature pipe 11 is used for heating the pouring liquid in a constant temperature box 9 at constant temperature, the pouring liquid in the constant temperature box 9 cannot be cooled and solidified in the pouring process, a telescopic rod 4 drives a die top plate 5 to slide downwards through a supporting rod 3, a positioning block 7 and a positioning groove 8 are connected with each other, the die top plate 5 and a die base 2 are connected with each other, a pressurizing 17 pump is started to enable the pouring liquid in the constant temperature box 9 to enter an outlet pipe 18 through an ingress pipe 16, plastic pouring is carried out through the pouring pipe 21, the pressurizing pump 17 is stopped to be poured into the pouring port 22 after pouring is finished, a water pump 2002 is started, cooling water 2007 in a cooling tank 2001 is enabled to be cooled and solidified through an ingress pipe 2003, the cooling water 2007 is enabled to be brought into the heat conducting pipe 2005, the cooling tank is enabled to slide downwards through the egress pipe 2006, the heat conducting pipe 2005 is enabled to be attached to the bottom end of a cavity 2005, the heat conducting pipe 1906 is enabled to be attached to the die base 1906, the heat conducting pipe is enabled to slide upwards, the plastic is enabled to be cooled down, the plastic is enabled to slide upwards, and the plastic is enabled to be cooled down 1903 is enabled to be pushed upwards, and the plastic is enabled to slide upwards, and the molding is enabled to be cooled, and the bottom the plastic is enabled to be pushed upwards, and the bottom is enabled to be cooled, and the bottom by a plastic molding plate is enabled to be pushed upwards and is convenient to be pushed to be in a heat.

According to the working process, the cooling assembly 20 is used for completing the pouring of the plastic mold poured in the molding cavity 6, so that the water pump 2002 is started to enable the cooling water 2007 in the cooling groove 2001 to enter through the water inlet pipe 2003, the cooling water 2007 is brought into the heat conducting pipe 2005 through the water delivery pipe 2004, and flows back into the cooling groove 2001 through the water outlet pipe 2006, so that the heat conducting pipe 2005 is attached to the bottom end of the molding cavity 6 in the conveying process of the cooling water 2007, the plastic mold poured in the molding cavity 6 is quickly absorbed, the plastic mold is quickly cooled and solidified to be molded, the molding efficiency of the device is improved, the production efficiency of the device is improved, the plastic mold in the molding cavity 6 is cooled and solidified to be molded through the ejection assembly 19, the telescopic column 1902 is driven to slide upwards through the support column 1901, the telescopic column 1902 is driven to slide upwards through the ejector plate 1903, the plastic mold solidified in the molding cavity 6 is ejected out of the mold base 2 through the ejector plate 1903, and the manual operation is saved, and the production efficiency of the device is further improved.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made therein without departing from the spirit and scope of the invention, which is defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. A plastic mold for high-precision product production and processing, comprising a device bottom plate (1), characterized in that: a mold base (2) is fixedly connected to the center of the top of the device bottom plate (1), a molding cavity (6) is provided at the top of the mold base (2), a positioning block (7) is fixedly connected to the top of the mold base (2), an ejection assembly (19) and a cooling assembly (20) are arranged inside the mold base (2), support rods (3) are fixedly connected to the left and right sides of the top of the device bottom plate (1), a telescopic rod (4) is slidably connected to the top of the support rod (3), a mold top plate (5) is fixedly connected to the top of the telescopic rod (4), a positioning groove (8) is provided at the bottom of the mold top plate (5), the positioning groove (8) and the positioning block (7) are mutually engaged, and two pouring ports (22) are provided on the right side of the top of the mold top plate (5). 2. A plastic mold for high-precision product production and processing according to claim 1, characterized in that: a constant temperature box (9) is fixedly connected to the center of the top of the mold top plate (5), a heating device (10) is arranged on the left side of the constant temperature box (9), and a plurality of constant temperature tubes (11) in a rectangular array are arranged inside the side wall of the constant temperature box (9), a heating tube (23) is fixedly connected to the left side of the constant temperature tube (11), and the bottom left side of the heating tube (23) is fixedly connected to the heating device (10). 3. A plastic mold for high-precision product production and processing according to claim 2, characterized in that: an injection port (12) is opened at the upper left corner of the top of the constant temperature box (9), and the outer surface of the bottom end of the injection port (12) is sleeved with a dust cover (13), and the top of the dust cover (13) is fixedly connected to two connecting rods (14), and the top of the connecting rod (14) is fixedly connected to a lifting handle (15), and the right side of the constant temperature box (9) is fixedly connected to the bottom, and the right side of the introduction pipe (16) is fixedly connected to a pressure pump (17), and the front and rear sides of the pressure pump (17) are fixedly connected to an outlet pipe (18), and the top of the outlet pipe (18) is fixedly connected to a pouring pipe (21), and the bottom end of the pouring pipe (21) is arranged at the top of the pouring port (22). 4. A plastic mold for high-precision product production and processing according to claim 1, characterized in that: the ejection assembly (19) includes two support columns (1901), the two support columns (1901) are located at the bottom end of the molding cavity (6) and are symmetrically arranged, the top ends of the two support columns (1901) are slidably connected with telescopic columns (1902), the top ends of the telescopic columns (1902) are fixedly connected with an ejection plate (1903), and the ejection plate (1903) is located inside the molding cavity (6) and slides up and down. 5. A plastic mold for high-precision product production and processing according to claim 1, characterized in that: the cooling component (20) comprises a cooling groove (2001), the cooling groove (2001) is located at the inner bottom end of the mold base (2), cooling water (2007) is arranged in the cooling groove (2001), a water pump (2002) is arranged on the left side of the interior of the cooling groove (2001), and a water inlet pipe (2003) is arranged at the top of the water pump (2002) ) and a water pipe (2004), the water pipe (2004) being arranged on the right side of the water inlet pipe (2003), the top end of the water pipe (2004) being fixedly connected to a heat conduction pipe (2005), the heat conduction pipe (2005) being arranged at the bottom end of the molding cavity (6), the right bottom end of the heat conduction pipe (2005) being fixedly connected to a water outlet pipe (2006), the bottom end of the heat conduction pipe (2005) being arranged inside the cooling tank (2001).