CN118003548A - An injection molding device with automatic chip embedding function for electric vehicle license plate production - Google Patents

Abstract

The present invention relates to the technical field of injection molding devices for producing electric vehicle license plates, and discloses an injection molding device with an automatic chip embedding function for producing electric vehicle license plates, the injection molding device with an automatic chip embedding function for producing electric vehicle license plates comprising a bed body, a first module track being installed on the bed body, a first slide being slidably installed on the first module track, a second module track being installed on the first slide seat, a second slide being installed on the second module track, a connecting rod being installed on the second slide seat, a clamping piece being installed on the connecting rod, a chip tray being placed on one side of the table top of the bed body, and starting the second module track can conveniently control the clamping piece to move down and clamp the chip through the second slide seat, and at the same time, starting the first module track can make the first slide seat drive the clamping piece to move to the top of the lower mold, and then starting the second module track can conveniently control the clamping piece to put the chip into the lower mold, which is conducive to realizing the automatic embedding of the chip in the mold.

Description

An injection molding device with automatic chip embedding function for electric vehicle license plate production

Technical Field

The invention relates to the technical field of injection molding devices for producing electric vehicle license plates, and in particular to an injection molding device with an automatic chip embedding function for producing electric vehicle license plates.

Background technique

License plates are commonly known as license plates. License plates are plates hung on the front and back of the car. They are usually made of aluminum, iron, plastic or paper. The car's registration number, registration area or other relevant information is engraved on it. License plates have the same size and are generally processed and molded by injection molding. There is a point in the license plate, which is the location of the chip in the license plate. Generally, the chip is embedded in the license plate. Therefore, an injection molding device that can embed the chip is required when injecting the license plate.

When using existing electric vehicle license plate injection molding molds, most of them require two independent upper and lower mold plates for mold closing operations, and when embedding the chip, it is mostly done manually, and there is no automatic chip embedding function. It is easy for position deviation to occur during the chip embedding process, which leads to reduced production efficiency of the license plate.

Summary of the invention

The object of the present invention is to provide an injection molding device with a chip automatic embedding function for producing electric vehicle license plates, so as to solve the problems raised in the above-mentioned background technology.

In order to solve the above technical problems, the present invention provides the following technical solutions: an injection molding device with an automatic chip embedding function for producing electric vehicle license plates, the injection molding device with an automatic chip embedding function for producing electric vehicle license plates comprises a bed, a lower mold is installed on the table top of the bed, and a lifter is installed on the top of the bed, an upper mold is installed on the lifter, a first module rail is installed on the bed, a first slide is slidably installed on the first module rail, a second module rail is installed on the first slide, a second module rail is installed on the second slide, a connecting rod is installed on the second slide, and the connecting rod is installed on the connecting rod. A clamping part is installed on the rod, and a chip tray is placed on one side of the table top of the bed. When the electric license plate is produced by injection molding, the second module track is started so that the second slide can drive the clamping part to move down through the connecting rod, which is convenient for the clamping part to clamp the chip in the chip tray. After the chip is clamped, the clamping part is lifted. At the same time, the first module track is started so that the first slide can drive the clamping part to move to the top of the lower mold, and then the second module track is started to facilitate the control of the clamping part to place the chip into the lower mold, which is conducive to the automatic embedding of the chip in the mold, and the operation of embedding the chip in the license plate is realized after the upper mold and the lower mold are combined for injection molding.

As a preferred technical solution, a circulating cooling component, a circulating primary utilization component and a circulating secondary utilization component are provided on the bed body. Rapid cooling of the injection molded parts is achieved through the circulating cooling component, and the operation of the circulating cooling component can realize power drive for the circulating primary utilization component and the circulating secondary utilization component.

As a preferred technical solution, the circulating cooling assembly includes a chamber, a cooling box, a pump, a suction tube, a liquid infusion tube, a perforation, a cooling cavity, a reflux pipe and a cooling plate;

The bed is provided with a chamber, in which a cooling box and a pump are installed, the input end of the pump is connected to the output end of the cooling box through a suction pipe, and an infusion pipe is installed on the output end of the pump, the top of the chamber is symmetrically provided with two groups of perforations, a cooling chamber is provided in the lower mold, the infusion pipe passes through one of the perforations and is connected with the cooling chamber, the cooling chamber is connected to the input end of the cooling box through a return pipe, the return pipe passes through another perforation, a refrigeration plate is installed in the cooling box, when the mold is closed for injection molding, the pump is started so that the suction pipe can suck the coolant in the cooling box, and then the coolant can be transported to the cooling chamber through the infusion pipe, so that the coolant absorbs heat for cooling, at the same time, the coolant that absorbs heat in the cooling chamber can flow back to the cooling box through the return pipe, so that the refrigeration plate can cool down the coolant carrying heat, thereby ensuring the cooling effect of the coolant, so that the coolant can continue to cool down in the circulation flow.

As a preferred technical solution, the circulating primary utilization assembly includes a tank body, a piston, a first supporting spring, a connecting pipe, an electric one-way valve, a transmission column and a sliding hole;

A tank body is installed on the cooling box, and a piston is slidably installed in the tank body. The piston is connected to the tank body through a first supporting spring. Two groups of connecting pipes are installed at the bottom of the tank body, and the two groups of connecting pipes are respectively connected to the infusion pipe and the return pipe, and electric one-way valves are arranged on the two groups of connecting pipes. A transmission column is installed on the piston, and a sliding hole is opened on the top of the tank body, and the transmission column passes through the sliding hole. When the coolant in the infusion pipe and the return pipe flows rapidly, the one-way limiting effect of the electric one-way valve can make the infusion pipe and the return pipe form an air pressure difference with the tank body through the connecting pipe, which is conducive to forming a negative pressure in the tank body, so that the piston can drive the transmission column to move downward under the action of the negative pressure.

As an optimal technical solution, the electric one-way valve is in an open state under normal circumstances, an end block is installed on the top of the transmission column, a first touch button is arranged on the end block, and a second touch button is arranged at the bottom of the piston, the first touch button and the second touch button are electrically connected to the electric one-way valve, when the piston moves to the lowest point in the tank body, the first touch button and the second touch button are touched at the same time, so that the first touch button and the second touch button can control the electric one-way valve to be temporarily closed, and during the pause of the electric one-way valve, the piston can be reset under the elastic force of the first support spring, thereby realizing the reciprocating movement of the piston in the tank body.

As a preferred technical solution, the circulating secondary utilization assembly includes a swivel, a drive rod, a slideway, a linkage rod and a transmission ring;

A swivel is rotatably installed on the top of the tank body, the transmission column passes through the swivel, and a slideway is provided on the side wall of the transmission column, the slideway is "spiral", a driving rod is rotatably installed on the swivel, the driving rod is inserted in the slideway, a linkage rod is installed on the swivel, and a transmission ring is installed on the linkage rod. When the transmission column moves downward with the piston, the "spiral" slideway can be used to squeeze the driving rod during the downward movement of the transmission column, so that the driving rod can drive the swivel to rotate circumferentially, and the swivel can drive the transmission ring to rotate synchronously through the linkage rod during the rotation process. At the same time, the reciprocating movement of the piston can realize the continuous rotation of the transmission ring during the injection cooling process.

As a preferred technical solution, the recycling secondary utilization component also includes a lower hemisphere, a storage hole, an impact head, a second support spring, a transmission rod, a through hole, a C-shaped plate and a sphere;

A lower hemisphere is installed at the bottom of the transmission ring, a receiving hole is provided on the bed, the receiving hole is below the lower mold, an impact head is slidably installed in the receiving hole, the impact head is connected to the bottom of the receiving hole through a second supporting spring, a through hole is provided at the bottom of the receiving hole, a transmission rod is installed at the bottom of the impact head, the transmission rod passes through the through hole, and a C-shaped plate is installed at the bottom of the transmission rod, and a ball is installed on the C-shaped plate. When the transmission ring rotates, the transmission ring can drive the lower hemisphere to rotate synchronously, so that the lower hemisphere contacts the ball during the rotation process, and the lower hemisphere can squeeze the ball to move downward through the spherical surface of the ball and the lower hemisphere. At this time, the ball can drive the impact head in the receiving hole to compress the second supporting spring through the C-shaped plate and the transmission rod. When the lower hemisphere is separated from the ball, the impact head can quickly impact the lower mold under the elastic force of the second supporting spring, forming a vibration to the mold, which can make the injection liquid more uniform in the mold, reduce the gap between the injection liquids, and avoid the generation of bubbles, defects and other quality problems.

As an optimal technical solution, the C-shaped plate is provided with an embedding hole, in which a sphere is rolled and embedded. Since the sphere can roll in the embedding hole, it is beneficial to disperse the lateral impact force of the lower hemisphere on the sphere when the sphere contacts the lower hemisphere, thereby ensuring smooth rotation of the lower hemisphere.

As an optimal technical solution, a third slide is slidably installed on the first module track, a connecting plate is installed on the third slide, an electric telescopic rod is installed on the connecting plate, an adsorption piece is installed on the electric telescopic rod, and a conveying roller is arranged on the bed. When the injection molding of the electric license plate is completed, the third slide on the first module track is controlled to move so that the third slide can drive the adsorption piece to move above the injection-molded license plate. At this time, the adsorption piece can be controlled to adsorb and lift the license plate through the electric telescopic rod, and then the completed electric license plate can be placed on the conveying roller through the third slide to convey the electric license plate.

Compared with the prior art, the beneficial effects achieved by the present invention are:

When the electric license plate is produced by injection molding, the second module track is started, so that the second slide can drive the clamping part to move down through the connecting rod, which is convenient for the clamping part to clamp the chip in the chip tray. After the chip is clamped, the clamping part is lifted. At the same time, the first module track is started, so that the first slide can drive the clamping part to move to the top of the lower mold, and then the second module track is started to facilitate the control of the clamping part to place the chip into the lower mold, which is conducive to the automatic embedding of the chip in the mold, and the operation of embedding the chip in the license plate is realized after the upper mold and the lower mold are combined for injection molding.

When the mold is closed for injection molding, the pump is started so that the suction tube can suck the coolant in the cooling box, and then the coolant can be transported to the cooling chamber through the infusion tube, so that the coolant absorbs heat for cooling. At the same time, the coolant that absorbs heat in the cooling chamber can flow back to the cooling box through the reflux pipe, so that the refrigeration plate can cool down the coolant carrying heat, thereby ensuring the cooling effect of the coolant and allowing the coolant to continue to cool down during the circulation flow.

When the coolant in the infusion tube and the return tube flows rapidly, negative pressure is formed in the tank body through the electric one-way valve and the connecting tube, so that the piston drives the transmission column to move downward under the action of the negative pressure; when the piston moves to the lowest point in the tank body, the first touch button and the second touch button can control the electric one-way valve to be temporarily closed; during the pause of the electric one-way valve, the piston can be reset under the elastic force of the first support spring, thereby realizing the reciprocating movement of the piston in the tank body.

When the transmission column moves downward with the piston, the driving rod can drive the swivel to rotate circumferentially, and the swivel can drive the transmission ring to rotate synchronously through the linkage rod, so that the lower hemisphere squeezes the sphere to move downward. At this time, the sphere can drive the impact head to compress the second supporting spring through the C-plate and the transmission rod. When the lower hemisphere separates from the sphere, the impact head can quickly impact the lower mold under the elastic force of the second supporting spring, forming vibration to the mold, which can make the injection liquid more uniform in the mold, reduce the gap between the injection liquids, and avoid quality problems such as bubbles and defects.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are used to provide a further understanding of the present invention and constitute a part of the specification. Together with the embodiments of the present invention, they are used to explain the present invention and do not constitute a limitation of the present invention. In the accompanying drawings:

FIG1 is a schematic diagram of the structure of the present invention from a first viewing angle;

FIG2 is a schematic diagram of the structure of the present invention from a second viewing angle;

FIG3 is a schematic diagram of a first cross-sectional structure of the present invention;

FIG4 is a schematic diagram of a second cross-sectional structure of the present invention;

FIG5 is an enlarged structural schematic diagram of point A in FIG3;

FIG6 is an enlarged structural diagram of point B in FIG4;

FIG. 7 is an enlarged structural schematic diagram of point C in FIG. 4 .

In the figure: 1, bed; 2, lower mold; 3, lifter; 4, upper mold; 5, first mold track; 6, first slide; 7, second mold track; 8, second slide; 9, connecting rod; 10, clamping member; 11, chip tray; 12, third slide; 13, connecting plate; 14, electric telescopic rod; 15, adsorption member; 16, conveyor roller;

17. Circulation cooling assembly; 1701. Chamber; 1702. Cooling box; 1703. Pump; 1704. Suction tube; 1705. Infusion tube; 1706. Perforation; 1707. Cooling chamber; 1708. Reflux tube; 1709. Refrigeration sheet;

18. Circulation primary utilization assembly; 1801. tank body; 1802. piston; 1803. first support spring; 1804. connecting pipe; 1805. electric one-way valve; 1806. transmission column; 1807. sliding hole; 1808. end block; 1809. first touch button; 1810. second touch button;

19. Circular secondary utilization assembly; 1901. swivel; 1902. drive rod; 1903. slideway; 1904. linkage rod; 1905. transmission ring; 1906. lower hemisphere; 1907. storage hole; 1908. impact head; 1909. second support spring; 1910. transmission rod; 1911. through hole; 1912. C-type plate; 1913. embedded hole; 1914. sphere.

Detailed ways

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Embodiment: As shown in Figures 1 to 4, the present invention provides the following technical solutions: An injection molding device with an automatic chip embedding function for producing electric vehicle license plates, the injection molding device with an automatic chip embedding function for producing electric vehicle license plates comprising a bed 1, a lower mold 2 is installed on the table top of the bed 1, and a lifter 3 is installed on the top of the bed 1, an upper mold 4 is installed on the lifter 3, a first module rail 5 is installed on the bed 1, a first slide 6 is slidably installed on the first module rail 5, a second module rail 7 is installed on the first slide 6, a second slide 8 is installed on the second module rail 7, a connecting rod 9 is installed on the second slide 8, and a clamp 10 is installed on the connecting rod 9. For example, the clamp 10 is The electric suction cup can adsorb and clamp the chip by running the electric suction cup. A chip tray 11 is placed on one side of the table top of the bed 1. When the electric license plate is produced by injection molding, the second module track 7 is started, so that the second slide 8 can drive the clamping part 10 to move down through the connecting rod 9, which is convenient for the clamping part 10 to clamp the chip in the chip tray 11. After the chip is clamped, the clamping part 10 is lifted. At the same time, the first module track 5 is started, so that the first slide 6 can drive the clamping part 10 to move to the top of the lower mold 2, and then the second module track 7 is started, which is convenient for controlling the clamping part 10 to put the chip into the lower mold 2, which is conducive to realizing the automatic embedding of the chip in the mold, and is convenient for the upper mold 4 and the lower mold 2 to be molded together for injection molding to realize the operation of embedding the chip in the license plate.

The bed body 1 is provided with a circulating cooling component 17, a circulating primary utilization component 18 and a circulating secondary utilization component 19. The circulating cooling component 17 is used to achieve rapid cooling of the injection molded parts, and the operation of the circulating cooling component 17 can realize power drive for the circulating primary utilization component 18 and the circulating secondary utilization component 19.

As shown in FIGS. 1 to 5 , the circulating cooling assembly 17 includes a chamber 1701, a cooling box 1702, a pump 1703, a liquid suction tube 1704, a liquid infusion tube 1705, a perforation 1706, a cooling cavity 1707, a return pipe 1708 and a cooling plate 1709;

The bed body 1 is provided with a chamber 1701, in which a cooling box 1702 and a pump 1703 are installed, the input end of the pump 1703 is connected to the output end of the cooling box 1702 through a suction pipe 1704, and a liquid infusion pipe 1705 is installed on the output end of the pump 1703. Two groups of through holes 1706 are symmetrically opened on the top of the chamber 1701, and a cooling cavity 1707 is provided in the lower mold 2. The liquid infusion pipe 1705 passes through one of the through holes 1706 and is connected to the cooling cavity 1707. The cooling cavity 1707 is connected to the input end of the cooling box 1702 through a reflux pipe 1708. The reflux pipe 1708 Another through hole 1706 is passed through, and a refrigeration plate 1709 is installed in the cooling box 1702. When the mold is closed for injection molding, the pump 1703 is started so that the suction tube 1704 can suck the coolant in the cooling box 1702, and then the coolant can be transported to the cooling cavity 1707 through the infusion tube 1705, so that the coolant absorbs heat for cooling. At the same time, the coolant that absorbs heat in the cooling cavity 1707 can flow back to the cooling box 1702 through the reflux pipe 1708, so that the refrigeration plate 1709 can cool down the coolant carrying heat, thereby ensuring the cooling effect of the coolant and facilitating the coolant to continue to cool down during the circulation flow.

As shown in FIGS. 3 to 6 , the recycling primary utilization assembly 18 includes a tank 1801 , a piston 1802 , a first support spring 1803 , a connecting pipe 1804 , an electric one-way valve 1805 , a transmission column 1806 and a sliding hole 1807 ;

The cooling box 1702 is provided with a tank body 1801, a piston 1802 is slidably installed in the tank body 1801, the piston 1802 is connected to the tank body 1801 through a first support spring 1803, two groups of connecting pipes 1804 are installed at the bottom of the tank body 1801, the two groups of connecting pipes 1804 are respectively connected to the infusion pipe 1705 and the return pipe 1708, and the two groups of connecting pipes 1804 are provided with electric one-way valves 1805, and the piston 1802 is provided with a transmission column 1806 A sliding hole 1807 is provided on the top of the tank body 1801, and the transmission column 1806 passes through the sliding hole 1807. When the coolant in the infusion tube 1705 and the return tube 1708 flows rapidly, the one-way restriction effect of the electric one-way valve 1805 can form an air pressure difference between the infusion tube 1705 and the return tube 1708 and the tank body 1801 through the connecting tube 1804, which is conducive to forming a negative pressure in the tank body 1801, so that the piston 1802 can drive the transmission column 1806 to move downward under the action of the negative pressure.

The electric one-way valve 1805 is in an open state under normal circumstances, and an end block 1808 is installed on the top of the transmission column 1806. A first touch button 1809 is arranged on the end block 1808, and a second touch button 1810 is arranged at the bottom of the piston 1802. The first touch button 1809 and the second touch button 1810 are electrically connected to the electric one-way valve 1805. When the piston 1802 moves to the lowest point in the tank body 1801, the first touch button 1809 and the second touch button 1810 are touched at the same time, so that the first touch button 1809 and the second touch button 1810 can control the electric one-way valve 1805 to be temporarily closed. During the pause of the electric one-way valve 1805, the piston 1802 can be reset under the elastic force of the first support spring 1803, thereby realizing the reciprocating movement of the piston 1802 in the tank body 1801.

As shown in FIGS. 3-4 and 6-7 , the circulating secondary utilization assembly 19 includes a swivel 1901 , a driving rod 1902 , a slideway 1903 , a linkage rod 1904 and a transmission ring 1905 ;

The top of the tank body 1801 is rotatably mounted with a swivel 1901, the transmission column 1806 penetrates the swivel 1901, and a slideway 1903 is provided on the side wall of the transmission column 1806, the slideway 1903 is in a "spiral" shape, a driving rod 1902 is rotatably mounted on the swivel 1901, the driving rod 1902 is inserted in the slideway 1903, a linkage rod 1904 is installed on the swivel 1901, and a transmission ring 1905 is installed on the linkage rod 1904. When the plug 1802 moves downward, the "spiral" slide 1903 can be used to squeeze the driving rod 1902 during the downward movement of the transmission column 1806, so that the driving rod 1902 can drive the swivel 1901 to rotate in a circumferential direction, and the swivel 1901 can drive the transmission ring 1905 to rotate synchronously through the linkage rod 1904 during the rotation process. At the same time, the reciprocating movement of the piston 1802 can realize the continuous rotation of the transmission ring 1905 during the injection cooling process.

The recycling secondary utilization assembly 19 also includes a lower hemisphere 1906, a receiving hole 1907, an impact head 1908, a second support spring 1909, a transmission rod 1910, a through hole 1911, a C-shaped plate 1912 and a sphere 1914;

The bottom of the transmission ring 1905 is installed with a lower hemisphere 1906, the bed 1 is provided with a storage hole 1907, the storage hole 1907 is located below the lower mold 2, an impact head 1908 is slidably installed in the storage hole 1907, the impact head 1908 is connected to the bottom of the storage hole 1907 through a second support spring 1909, the bottom of the storage hole 1907 is provided with a through hole 1911, a transmission rod 1910 is installed at the bottom of the impact head 1908, the transmission rod 1910 passes through the through hole 1911, and a C-shaped plate 1912 is installed at the bottom of the transmission rod 1910, and a ball 1914 is installed on the C-shaped plate 1912. When the transmission ring 1905 rotates, the transmission ring 1905 can drive The lower hemisphere 1906 rotates synchronously so that the lower hemisphere 1906 contacts the sphere 1914 during the rotation. Through the cooperation between the sphere 1914 and the spherical surface of the lower hemisphere 1906, the lower hemisphere 1906 can squeeze the sphere 1914 to move downward. At this time, the sphere 1914 can drive the impact head 1908 in the storage hole 1907 to compress the second support spring 1909 through the C-shaped plate 1912 and the transmission rod 1910. When the lower hemisphere 1906 is separated from the sphere 1914, the impact head 1908 can quickly impact the lower mold 2 under the elastic force of the second support spring 1909, forming vibration to the mold, which can make the injection liquid more uniform in the mold, reduce the gap between the injection liquid, and avoid the generation of bubbles, defects and other quality problems.

The C-shaped plate 1912 is provided with an embedding hole 1913, in which a ball 1914 is roamingly embedded. Since the ball 1914 can roll in the embedding hole 1913, when the ball 1914 contacts the lower hemisphere 1906, the lateral impact force of the lower hemisphere 1906 on the ball 1914 is dispersed, thereby ensuring smooth rotation of the lower hemisphere 1906.

A third slide 12 is slidably installed on the first module rail 5, a connecting plate 13 is installed on the third slide 12, an electric telescopic rod 14 is installed on the connecting plate 13, an adsorption component 15 is installed on the electric telescopic rod 14, and a conveying roller 16 is arranged on the bed 1. When the injection molding of the electric license plate is completed, the third slide 12 on the first module rail 5 is controlled to move so that the third slide 12 can drive the adsorption component 15 to move above the injection-molded license plate. At this time, the adsorption component 15 can be controlled to adsorb and lift the license plate through the electric telescopic rod 14, and then the completed electric license plate can be placed on the conveying roller 16 through the third slide 12 to convey the electric license plate.

Working principle of the present invention:

When the electric license plate is produced by injection molding, the second module track 7 is started, so that the second slide 8 can drive the clamping part 10 to move downward through the connecting rod 9, so that the clamping part 10 can clamp the chip in the chip tray 11. After the chip is clamped, the clamping part 10 is lifted. At the same time, the first module track 5 is started, so that the first slide 6 can drive the clamping part 10 to move to the top of the lower mold 2, and then the second module track 7 is started, which is convenient for controlling the clamping part 10 to put the chip into the lower mold 2, which is conducive to realizing the automatic embedding of the chip in the mold, and is convenient for the upper mold 4 and the lower mold 2 to be molded together for injection molding to realize the operation of embedding the chip in the license plate.

When the mold is closed for injection molding, the pump 1703 is started so that the suction tube 1704 can suck the coolant in the cooling box 1702, and then the coolant can be transported to the cooling chamber 1707 through the infusion tube 1705, so that the coolant absorbs heat for cooling. At the same time, the coolant that absorbs heat in the cooling chamber 1707 can flow back to the cooling box 1702 through the reflux pipe 1708, so that the refrigeration plate 1709 can cool down the coolant carrying heat, thereby ensuring the cooling effect of the coolant and facilitating the coolant to continue to cool down during the circulation flow.

When the coolant in the infusion tube 1705 and the return tube 1708 flows rapidly, the one-way limiting effect of the electric one-way valve 1805 can form an air pressure difference between the infusion tube 1705 and the return tube 1708 through the connecting tube 1804 and the tank body 1801, which is conducive to the formation of negative pressure in the tank body 1801, so that the piston 1802 can drive the transmission column 1806 to move downward under the action of negative pressure. When the piston 1802 moves to the lowest point in the tank body 1801, the first touch button 1809 and the second touch button 1810 are touched at the same time, so that the first touch button 1809 and the second touch button 1810 can control the electric one-way valve 1805 to be temporarily closed. During the pause of the electric one-way valve 1805, the piston 1802 can be reset under the elastic force of the first support spring 1803, thereby realizing the reciprocating movement of the piston 1802 in the tank body 1801.

When the transmission column 1806 moves downward with the piston 1802, the "spiral" slideway 1903 can be used to squeeze the driving rod 1902 during the downward movement of the transmission column 1806, so that the driving rod 1902 can drive the rotating ring 1901 to rotate in a circumferential direction, and the rotating ring 1901 can drive the transmission ring 1905 to rotate synchronously through the linkage rod 1904 during the rotation process. At the same time, the cyclic reciprocating movement of the piston 1802 can realize the continuous rotation of the transmission ring 1905 during the injection cooling process. When the transmission ring 1905 rotates, the transmission ring 1905 can drive the lower hemisphere 1906 to rotate synchronously, so that the lower hemisphere 19 06 contacts with the ball 1914 during the rotation process, and through the cooperation between the ball 1914 and the spherical surface of the lower hemisphere 1906, the lower hemisphere 1906 can squeeze the ball 1914 to move downward. At this time, the ball 1914 can drive the impact head 1908 in the storage hole 1907 to compress the second support spring 1909 through the C-shaped plate 1912 and the transmission rod 1910. When the lower hemisphere 1906 is separated from the ball 1914, the impact head 1908 can quickly impact the lower mold 2 under the elastic force of the second support spring 1909, forming vibration to the mold, which can make the injection liquid more uniform in the mold, reduce the gap between the injection liquids, and avoid the generation of bubbles, defects and other quality problems.

It will be apparent to those skilled in the art that the invention is not limited to the details of the exemplary embodiments described above and that the invention can be implemented in other specific forms without departing from the spirit or essential features of the invention. Therefore, the embodiments should be considered exemplary and non-limiting in all respects, and the scope of the invention is defined by the appended claims rather than the foregoing description, and it is intended that all variations within the meaning and scope of the equivalent elements of the claims be included in the invention. Any reference numeral in a claim should not be considered as limiting the claim to which it relates.

Claims (9)

1. Electronic license plate production is with device of moulding plastics that has chip automation and bury function, its characterized in that: this electronic license plate production is with injection molding device that has chip automation to bury function includes the bed body (1), install bed body (1) mesa on bed body (1) bed die (2), and install riser (3) at the top of bed body (1), install mould (4) on riser (3), install first module track (5) on bed body (1), slidable mounting has first slide (6) on first module track (5), install second module track (7) on first slide (6), install second slide (8) on second module track (7), install connecting rod (9) on second slide (8), install holder (10) on connecting rod (9), chip tray (11) have been placed to mesa one side of bed body (1).

2. The injection molding device with the chip automatic embedding function for producing the electric license plate according to claim 1, wherein the injection molding device is characterized in that: be provided with circulation cooling module (17), circulation one-level utilization subassembly (18) and circulation second grade utilization subassembly (19) on bed body (1), realize the quick cooling of injection molding through circulation cooling module (17), and utilize the operation of circulation cooling module (17) can be for circulation one-level utilization subassembly (18) and circulation second grade utilization subassembly (19) realization power drive.

3. The injection molding device with the chip automatic embedding function for producing the electric license plate according to claim 2, wherein the injection molding device is characterized in that: the circulating cooling assembly (17) comprises a chamber (1701), a cooling box (1702), a pump (1703), a liquid suction pipe (1704), an infusion pipe (1705), a perforation (1706), a cooling cavity (1707), a return pipe (1708) and a refrigerating sheet (1709);

The cooling device comprises a bed body (1), wherein a cavity (1701) is arranged in the bed body (1), a cooling box (1702) and a pump (1703) are arranged in the cavity (1701), the input end of the pump (1703) is connected with the output end of the cooling box (1702) through a liquid suction pipe (1704) in an image mode, a transfusion pipe (1705) is arranged on the output end of the pump (1703), two groups of perforations (1706) are symmetrically arranged at the top of the cavity (1701), a cooling cavity (1707) is arranged in a lower die (2), the transfusion pipe (1705) penetrates through one of the perforations (1706) and is communicated with the cooling cavity (1707), the cooling cavity (1707) is communicated with the input end of the cooling box (1702) through a backflow pipe (1708), the backflow pipe (1708) penetrates through the other perforation (1706), and a refrigerating piece (1709) is arranged in the cooling box (1702).

4. The injection molding device with the chip automatic embedding function for producing the electric license plate according to claim 3, wherein the injection molding device is characterized in that: the circulating primary utilization assembly (18) comprises a tank body (1801), a piston (1802), a first supporting spring (1803), a connecting pipe (1804), an electric one-way valve (1805), a transmission column (1806) and a sliding hole (1807);

Install jar body (1801) on cooling tank (1702), install piston (1802) in jar body (1801) sliding mounting, piston (1802) are connected through first supporting spring (1803) with jar body (1801), two sets of connecting pipes (1804) are installed to the bottom of jar body (1801), and two sets of connecting pipes (1804) are connected with transfer line (1705) and back flow (1708) respectively, and are provided with electronic check valve (1805) on two sets of connecting pipes (1804), install drive post (1806) on piston (1802), slide hole (1807) have been seted up at the top of jar body (1801), drive post (1806) run through slide hole (1807).

5. The injection molding device with the chip automatic embedding function for producing the electric license plate according to claim 4, wherein the injection molding device is characterized in that: the electric check valve (1805) is in an open state in a normal state, an end block (1808) is arranged at the top of the transmission column (1806), a first touch button (1809) is arranged on the end block (1808), a second touch button (1810) is arranged at the bottom of the piston (1802), and the first touch button (1809) and the second touch button (1810) are electrically connected with the electric check valve (1805).

6. The injection molding device with the chip automatic embedding function for producing the electric license plate according to claim 5, wherein the injection molding device is characterized in that: the circulating secondary utilization assembly (19) comprises a swivel (1901), a driving rod (1902), a slideway (1903), a linkage rod (1904) and a transmission ring (1905);

Swivel (1901) is installed in the top rotation of jar body (1801), transmission post (1806) runs through swivel (1901), and is equipped with slide (1903) on the lateral wall of transmission post (1806), slide (1903) are "spiral" form, rotate on swivel (1901) and install actuating lever (1902), actuating lever (1902) alternate in slide (1903), install gangbar (1904) on swivel (1901), install drive ring (1905) on gangbar (1904).

7. The injection molding device with the chip automatic embedding function for producing the electric license plate according to claim 6, wherein the injection molding device is characterized in that: the circulating secondary utilization assembly (19) further comprises a lower hemisphere (1906), a containing hole (1907), an impact head (1908), a second supporting spring (1909), a transmission rod (1910), a through hole (1911), a C-shaped plate (1912) and a sphere (1914);

The lower hemisphere (1906) is installed to the bottom of drive ring (1905), accomodate hole (1907) have been seted up on the bed body (1), accomodate hole (1907) are in the below of bed mould (2), slidable mounting has impact head (1908) in accomodate hole (1907), impact head (1908) are connected through second supporting spring (1909) with the bottom of accomodating hole (1907), through-hole (1911) have been seted up to the bottom of accomodating hole (1907), drive rod (1910) are installed to the bottom of impact head (1908), drive rod (1910) run through-hole (1911), and install C template (1912) in the bottom of drive rod (1910), install spheroid (1914) on C template (1912).

8. The injection molding device with the chip automatic embedding function for producing the electric license plate of claim 7, wherein the injection molding device is characterized in that: and the C-shaped plate (1912) is provided with an embedded hole (1913), and a sphere (1914) is embedded in the embedded hole (1913) in a rolling way.

9. The injection molding device with a chip automatic embedding function for producing an electric license plate according to any one of claims 1 to 8, wherein: the novel bed is characterized in that a third sliding seat (12) is slidably mounted on the first module track (5), a connecting plate (13) is mounted on the third sliding seat (12), an electric telescopic rod (14) is mounted on the connecting plate (13), an adsorption piece (15) is mounted on the electric telescopic rod (14), and a conveying roller way (16) is arranged on the bed body (1).