Spiral waterway structure of thermal forming cup bottom mold
Technical Field
The utility model relates to a water cooling structure of a thermal forming die, in particular to a spiral water path structure of a thermal forming cup bottom die.
Background
At present, when a thermal forming turnover mould is used for forming, whether the water circulation cooling effect of a cup bottom mould is reasonable or not is very important, and the forming of a product is influenced. According to the conventional mould, a water channel of the cup bottom enters the mould bottom from a water inlet of the cup returning rod and then flows out from a water outlet of the cup returning rod, so that the cup bottom is cooled. However, if the cup bottom is larger, the circulating cup bottom can flow out of the cup bottom before being cooled, the peripheral cooling effect of the cup bottom is particularly poor, and the water temperature of cooling water is often reduced, the water path is increased, and the water pressure is often increased in the past; in the other method, a water path flowing into the cup bottom is increased, and a water outlet flowing out of the cup bottom and entering the cup withdrawing rod is correspondingly reduced, so that the water circulation area can be increased, the cooling effect can be improved, but the cooling effect cannot be met; the cup bottom cooling effect can be improved by reducing the cup beating times, but the production efficiency is seriously reduced.
Disclosure of Invention
An object of the utility model is to prior art current situation, provide a thermoforming bottom of cup mould spiral waterway structure, can increase bottom of cup water route circulation area, improve hydrologic cycle efficiency, have better cooling effect.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
the utility model provides a thermoforming bottom of cup mould spiral waterway structure, mainly has moves back a glass pole and bottom of cup hydroecium, bottom of cup hydroecium top is connected with the bottom of cup connecting block, is the heliciform on the bottom of cup connecting block face, moves back the water inlet intercommunication that has the inlet tube in the cup pole and is located the bottom of cup connecting block centre, moves back the delivery port intercommunication that has the outlet pipe and is located bottom of cup connecting block external diameter in the cup pole, and the outlet pipe upper portion forms the annular of water.
Furthermore, the outer wall of the water chamber at the bottom of the cup is in threaded connection with the inner wall of the connecting block at the bottom of the cup.
The utility model has the advantages that: adopt spiral helicine bottom of cup connecting block and bottom of cup hydroecium to combine as an organic whole sub-assembly, the spiral water route that forms can cover whole bottom of cup area, and the cooling water is from bottom of cup connecting block middle part extrinsic cycle, improves water cycle efficiency, can take away the goods heat fast, guarantees the yield of goods, and its overall structure reasonable in design helps improving production efficiency, reduction in production cost.
Description of the drawings:
FIG. 1 is a sectional view of the overall structure of the present invention;
fig. 2 is a schematic structural diagram of the connecting block at the bottom of the cup in the present invention.
The specific implementation mode is as follows:
please refer to fig. 1 and fig. 2, which are schematic structural diagrams of the preferred embodiment of the present invention, the present invention relates to a spiral water path structure of a thermal forming cup bottom mold, which mainly comprises a cup withdrawing rod 1 and a cup bottom water chamber 2, wherein the top of the cup bottom water chamber 2 is connected to a cup bottom connecting block 3, the cup bottom connecting block 3 is in spiral shape, the cup withdrawing rod 1 is provided with a water inlet pipe 11 and is communicated with a water inlet 31 located in the middle of the cup bottom connecting block 3, the cup withdrawing rod 1 is provided with a water outlet pipe 12 and is communicated with a water outlet 32 located at the outer diameter of the cup bottom connecting block 3, cooling water enters the middle of the cup bottom connecting block 3 from the water inlet pipe 11, and then enters the water outlet pipe 12 from the.
Specifically, bottom of cup connecting block 3 is with goods bottom direct contact, and bottom of cup connecting block 3's spiral water route can be adjusted according to actual production demand, and if need the contact surface bigger, then spiral water route cross-section is little, and more spiral number of turns is more intensive. The cooling water is spread from the middle part of the cup bottom connecting block 3 to the outside in a rotating way, so that the water cooling efficiency can be improved.
The outer wall of the cup bottom water chamber 2 is in threaded connection with the inner wall of the cup bottom connecting block 3, so that the installation is convenient, the cup bottom connecting blocks 3 of different models and sizes can be replaced according to different production requirements, and the production requirements of different products are met.
In order to ensure that the direction of the water outlet pipe 12 of the cup withdrawing rod 1 and the water outlet 32 of the cup bottom connecting block 3 do not need to be designed in a directional mode, the water forming ring groove 121 formed in the upper portion of the water outlet pipe 12 can be in butt joint with the water outlet 32, namely no matter how the cup bottom connecting block 3 is assembled, the water of the water outlet 32 can be guaranteed to enter the water outlet pipe 12 through the water ring groove 121.
Of course, the above illustration is only a preferred embodiment of the present invention, and the scope of the present invention is not limited thereto, so all equivalent changes made in the principle of the present invention should be included in the protection scope of the present invention.