Cooling device for glass bottle production mold
The glass bottle production mold cooling device, which combines a three-dimensional slide table and a conical ventilation duct with an axial flow fan, solves the problems of fixed mold position and uneven airflow distribution, enabling flexible adjustment of mold position and efficient cooling, and reducing energy consumption.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU JINDIAN GLASS CO LTD
- Filing Date
- 2025-05-12
- Publication Date
- 2026-06-05
AI Technical Summary
Traditional glass bottle production mold cooling devices cannot dynamically adjust the mold position, resulting in uneven airflow distribution, leading to localized overheating or insufficient cooling, and also causing energy waste.
A three-dimensional slide table and a conical ventilation duct are used in conjunction with an axial flow fan. The three-dimensional slide table allows for flexible adjustment of the mold position, while the conical ventilation duct and the axial flow fan form a concentrated and uniform airflow. A retractable annular guide hood covers the outside of the mold, and the axial flow fan can be used to select local air supply based on the number and location of the molds by starting and stopping the axial flow fan in different zones.
It enables flexible adjustment of mold position and uniform and efficient cooling, reducing energy consumption and improving cooling efficiency.
Smart Images

Figure CN224325274U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass bottle processing technology, specifically a cooling device for glass bottle production molds. Background Technology
[0002] In the glass bottle manufacturing process, rapid and uniform cooling of the mold is crucial for product quality and production efficiency. Traditional cooling devices mostly employ fixed air-cooling or water-cooling structures, which have the following shortcomings: fixed air-cooling systems struggle to adjust airflow direction according to the mold's shape and position, leading to localized overheating or insufficient cooling; the fixed mold position prevents adjustment in three-dimensional space, limiting the adaptability of the cooling process; and single-direction or full-power airflow easily results in energy waste. Therefore, there is an urgent need for a device capable of dynamically adjusting the mold position, optimizing airflow distribution, and improving cooling efficiency. Utility Model Content
[0003] The purpose of this invention is to solve the problems existing in the background art and provide a cooling device for glass bottle production molds.
[0004] This utility model achieves the above-mentioned objective through the following technical solution: A cooling device for glass bottle production molds includes a housing, a loading port on the side of the housing, and a through-hole on the top. A three-dimensional slide is provided inside the housing to move the glass bottle mold in the X / Y and Z directions. A hollow support plate for placing the glass bottle mold is connected to the three-dimensional slide to allow airflow to enter from the bottom of the mold. A conical ventilation pipe is connected to the inner top of the housing, the outlet of the ventilation pipe is connected to the through-hole, multiple axial flow fans are arranged on the inner wall of the ventilation pipe, and a retractable annular guide shroud is connected to the bottom of the ventilation pipe, the annular guide shroud being located between the ventilation pipe and the support plate.
[0005] Furthermore, the annular flow guide includes an annular telescopic cover, the bottom of which is connected to an ear plate, and connecting rods are connected to the four corners of the ear plate facing the telescopic cover.
[0006] Furthermore, cylinders are installed diagonally on the top surface of the housing, and the telescopic rods of the cylinders are connected to two of the connecting rods. The other two connecting rods pass through the top surface of the housing and guide the movement of the ear plate.
[0007] Furthermore, the diameter of the outlet of the conical ventilation duct is smaller than the diameter of its bottom inlet, and the axial flow fans connected to the inner wall of the ventilation duct are arranged in a rectangular pattern of two rows and two columns.
[0008] Furthermore, the three-dimensional slide includes a Z-axis lifting seat located at the bottom, the Z-axis lifting seat contains four evenly arranged hydraulic cylinders, an X-axis moving seat is connected to the Z-axis lifting seat, a Y-axis moving seat is connected to the X-axis moving seat, and the support plate is connected to the Y-axis moving seat.
[0009] Compared with the prior art, the beneficial effects of this utility model are:
[0010] 1. The mold position can be flexibly adjusted through a three-dimensional slide table (X / Y / Z direction). The conical ventilation pipe and axial flow fan work together to form a concentrated and uniform upward airflow, which accelerates the heat dissipation of the mold. The retractable annular guide shroud is controlled by a cylinder to cover the outside of the mold, reduce airflow loss and improve cooling efficiency. The axial flow fan can be started and stopped in sections, and local air supply can be selected according to the number and position of the mold to reduce energy consumption. Attached Figure Description
[0011] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0012] Figure 2 This is a schematic diagram of the interior of the shell in this utility model;
[0013] Figure 3 This is a schematic diagram of the ventilation duct, annular guide shroud, and axial flow fan in this utility model;
[0014] Figure 4 This is a schematic diagram of the three-dimensional slide and support plate in this utility model.
[0015] In the diagram: 1-shell, 2-three-dimensional slide, 3-support plate, 4-ventilation pipe, 5-axial flow fan, 6-annular guide shroud, 7-cylinder, 21-Z-axis lifting seat, 22-X-axis moving seat, 23-Y-axis moving seat, 61-telescopic cover, 62-ear plate, 63-connecting rod. Detailed Implementation
[0016] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0017] In the description of this utility model, it should be understood that the terms "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", and "outer" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0018] Combination Figures 1 to 4 The cooling device for a glass bottle production mold shown includes a housing 1. The housing 1 has a loading port on its side and a through-hole on its top. Inside the housing 1, there is a three-dimensional slide 2 that moves the glass bottle mold in the X / Y and Z directions. A hollow support plate 3 for placing the glass bottle mold is connected to the three-dimensional slide 2 to allow airflow to enter from the bottom of the mold. A conical ventilation pipe 4 is connected to the top of the housing 1. The air outlet of the ventilation pipe 4 is connected to the through-hole. Multiple axial flow fans 5 are arranged on the inner wall of the ventilation pipe 4. A retractable annular guide shroud 6 is connected to the bottom of the ventilation pipe 4 and is located between the ventilation pipe 4 and the support plate 3.
[0019] like Figure 2-3 As shown, the annular guide shield 6 includes an annular telescopic shield 61. Ear plates 62 are connected to the bottom of the telescopic shield 61, and connecting rods 63 are connected to the four corners of the ear plates 62 facing the telescopic shield 61. The telescopic shield 61 can use a metal telescopic shield as in the prior art, or it can be made of a high-temperature resistant plastic film with metal rings sewn at intervals on the outer or inner side of the plastic film to form the telescopic shield 61. Figure 1 As shown, cylinders 7 are installed diagonally on the top surface of the housing 1. The telescopic rods of the cylinders 7 are connected to two connecting rods 63. The other two connecting rods 63 pass through the top surface of the housing 1 and guide the ear plate 62 to move. When the glass bottle mold is placed on the hollow support plate 3, the two cylinders 7 are first activated to drive the ear plate 62 to move upward through the connecting rods 63. This causes the annular guide shroud 6 to retract upward, thereby creating space for the glass bottle mold to be placed on the hollow support plate 3.
[0020] like Figure 2 and Figure 4As shown, the three-dimensional slide table 2 includes a Z-axis lifting seat 21 located at the bottom. The Z-axis lifting seat 21 contains four evenly arranged hydraulic cylinders. An X-axis moving seat 22 is connected to the Z-axis lifting seat 21, and a Y-axis moving seat 23 is connected to the X-axis moving seat 22. A support plate 3 is connected to the Y-axis moving seat 23. In the three-dimensional slide table 2, the height of the support plate 3 can be adjusted by the hydraulic cylinders. The X-axis moving seat 22 and the Y-axis moving seat 23 can be controlled by their own motors to move the support plate 3 in the X and Y directions, respectively, thereby adjusting the position of the glass bottle mold. The X-axis moving seat 22 and the Y-axis moving seat 23 are existing mechanisms that use the cooperation of a motor, screw, and threaded moving block for movement, which will not be described in detail here.
[0021] like Figure 2-3 As shown, the diameter of the outlet of the conical ventilation pipe 4 is smaller than the diameter of its bottom inlet. The axial flow fans 5 connected to the inner wall of the ventilation pipe 4 are arranged in a rectangular pattern of two rows and two columns. In use, the cylinder 7 is used to lower the annular guide shroud 6 so that it can cover the glass bottle mold on the support plate 3. Then, according to the number and position of the glass bottle mold on the support plate 3, the axial flow fan 5 at the corresponding position above can be selected and started from the four axial flow fans 5, thereby generating an upward airflow to exhaust the heat on the glass bottle mold, thereby cooling it down.
[0022] The working principle of this utility model is as follows: The cylinder 7 is activated, the annular guide shroud 6 is retracted, and after freeing up space, the mold is placed on the hollow support plate 3 through the loading port. The Z-axis hydraulic cylinder of the three-dimensional slide table 2 adjusts the height of the mold, and the X / Y-axis motor drives the moving seat to position the mold in the optimal cooling area. Then, the cylinder 7 drives the guide shroud 6 to be lowered to cover the outside of the mold and form a closed air duct. The axial flow fan 5 at the corresponding position is activated. After the airflow is accelerated through the conical ventilation pipe 4, it penetrates the hollow structure at the bottom of the mold from bottom to top, takes away the heat and is discharged from the top through-hole. Thus, the position of the three-dimensional slide table 2 and the operation mode of the fan can be adjusted in real time according to the temperature distribution of the mold to achieve uniform and efficient cooling.
[0023] In addition, this utility model can be connected to a remote control, allowing the operator to control the operation of the cylinder, axial fan, and hydraulic cylinder and motor of the three-dimensional slide table separately.
[0024] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.
[0025] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. A cooling device for a glass bottle production mold, comprising a housing (1), wherein a loading port is provided on the side of the housing (1), and a through opening is provided on the top, characterized in that: The housing (1) is provided with a three-dimensional slide (2) that moves the glass bottle mold in the X / Y and Z directions. The three-dimensional slide (2) is connected to a hollow support plate (3) for placing the glass bottle mold so that airflow can enter from the bottom of the mold. A conical ventilation pipe (4) is connected to the top of the housing (1). The air outlet of the ventilation pipe (4) is connected to the through port. Multiple axial flow fans (5) are arranged on the inner wall of the ventilation pipe (4). A retractable annular guide shroud (6) is connected to the bottom of the ventilation pipe (4). The annular guide shroud (6) is located between the ventilation pipe (4) and the support plate (3).
2. The cooling device for glass bottle production molds according to claim 1, characterized in that: The annular flow guide (6) includes an annular telescopic cover (61), and the bottom of the telescopic cover (61) is connected to an ear plate (62). Connecting rods (63) are connected to the four corners of the ear plate (62) facing the telescopic cover (61).
3. The cooling device for glass bottle production molds according to claim 2, characterized in that: Cylinders (7) are installed diagonally on the top surface of the housing (1). The telescopic rods of the cylinders (7) are connected to two of the connecting rods (63). The other two connecting rods (63) pass through the top surface of the housing (1) and guide the ear plate (62) to move.
4. The cooling device for glass bottle production molds according to claim 3, characterized in that: The diameter of the outlet of the conical ventilation pipe (4) is smaller than the diameter of its bottom inlet. The axial flow fans (5) connected to the inner wall of the ventilation pipe (4) are arranged in a rectangular pattern of two rows and two columns.
5. The cooling device for glass bottle production molds according to claim 4, characterized in that: The three-dimensional slide (2) includes a Z-axis lifting seat (21) located at the bottom. The Z-axis lifting seat (21) contains four evenly arranged hydraulic cylinders. An X-axis moving seat (22) is connected to the Z-axis lifting seat (21). A Y-axis moving seat (23) is connected to the X-axis moving seat (22). The support plate (3) is connected to the Y-axis moving seat (23).