Air cooling device for glass bottle production
By combining a fan with compression and diversion technology and a three-dimensional air outlet structure, the problems of uneven cooling and high energy consumption in glass bottle production have been solved, achieving uniform cooling and high energy efficiency for glass bottles, improving product yield and simplifying equipment maintenance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SICHUAN BAOJING GLASS CO LTD
- Filing Date
- 2025-07-11
- Publication Date
- 2026-06-26
Smart Images

Figure CN224415513U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass bottle processing technology, and more specifically, to an air-cooling device for glass bottle production. Background Technology
[0002] In the glass bottle manufacturing process, the fired glass bottles reach extremely high temperatures and require effective cooling before further processing. Traditional cooling methods often involve natural cooling or direct blowing of cold air. However, glass is extremely sensitive to sudden temperature changes. If the cooling rate is too fast or the temperature difference between hot and cold is too large, thermal stress can easily cause the bottle to crack or even explode, resulting in decreased product yield and resource waste. Therefore, achieving efficient and safe cooling is crucial.
[0003] In pursuit of efficiency, some existing air-cooling devices often use multiple hot air blowers to directly blow hot air onto the bottle. This method is not only energy-intensive and noisy, but also results in uneven hot air distribution, making it difficult to accurately control the cooling gradient and still posing a high risk of breakage. In addition, the complex layout of multiple blowers increases the manufacturing cost and maintenance difficulty of the equipment. Therefore, in order to address the above technical problems, an air-cooling device for glass bottle production is proposed here. Utility Model Content
[0004] The purpose of this utility model is to provide an air-cooling device for glass bottle production. It adopts a fan in conjunction with compression and diversion technology to pressurize the airflow and deliver it precisely to the three-dimensionally distributed air outlet structure through multi-stage channels. The inclined and vertical hollow slats work together to spray a temperature-controlled airflow bidirectionally through array holes, realizing synchronous gradient cooling of both sides of the glass bottle. The hot air slow cooling process avoids cracking. The overall structure is simple, energy-saving and easy to maintain.
[0005] This utility model is achieved through the following technical solution:
[0006] A wind-cooling device for glass bottle production includes a main body. Multiple sets of vertically arranged mounting plates are fixedly connected to the inner side of the main body, dividing the internal space of the main body into multiple wind-cooling zones. A fixed base is fixedly connected to the top of each wind-cooling zone. Fixing strips are fixedly connected between the two sides of the fixed base and the inner side walls of the main body. Both the mounting plates and the fixing strips are hollow structures. A first air outlet is opened on the outside of the mounting plates, and a second air outlet is opened on the outside of the fixing strips. Multiple sets of equally spaced connecting strips are fixedly connected to the outside of the main body, and the connecting strips match the fixing strips. An air supply structure is installed between the connecting strips, the mounting plates, and the fixing strips. A mounting box is fixedly connected to the rear side of the main body. An air-generating structure is installed inside the mounting box, and an air guide structure is installed between the mounting box and the connecting strips.
[0007] Preferably, a support frame is fixedly connected to the upper side of the mounting plate.
[0008] Preferably, the fixing strip is installed at an angle.
[0009] Preferably, the number of the first air outlets is several groups arranged in an array, and the number of the second air outlets is several groups arranged in a horizontal direction.
[0010] Preferably, the air supply structure includes a first air inlet duct and a second air inlet duct. The first air inlet duct is located between the mounting plate, the equipment body, and the connecting strip, and the second air inlet duct is located between the fixing strip, the equipment body, and the connecting strip.
[0011] Preferably, the bottom of the mounting box is provided with a ventilation mesh.
[0012] Preferably, the air-generating structure includes a first fixed rod, a fan, a second fixed rod, and a thermoelectric component. The first and second fixed rods are both fixedly connected to the inside of the mounting box. The fan is fixedly connected to the outside of the first fixed rod, and the thermoelectric component is fixedly connected to the outside of the second fixed rod. A power supply is fixedly installed inside the mounting box, and the power supply is electrically connected to the fan and the thermoelectric component. A temperature sensor is fixedly connected inside the mounting box.
[0013] Preferably, the air guiding structure includes an air outlet, a compression pipe, a connecting pipe, and an exhaust hole. The air outlet is located on the upper side of the mounting box. The compression pipe is fixedly connected to the upper side of the mounting box and completely covers the air outlet. The connecting pipe is fixedly connected to the outside of the compression pipe and is fixedly connected to all the connecting strips. The exhaust hole is located between the connecting pipe and the connecting strips.
[0014] The technical solution of this utility model has at least the following beneficial effects:
[0015] This utility model proposes an air-cooling device for glass bottle production. Through a fan and a compression and diversion design, the airflow is concentrated, pressurized, and precisely delivered to a three-dimensionally distributed air outlet structure, significantly reducing energy consumption and operating costs. Inclined and vertical hollow slats work together to spray controllable temperature airflow bidirectionally through array holes, achieving synchronous gradient cooling of both sides of the glass bottle. In addition, the hot air slow cooling process avoids bottle cracking caused by sudden temperature changes, significantly improving product yield. It not only ensures the integrity and cooling uniformity of the glass bottle, but also improves cooling efficiency through optimized airflow design, while reducing equipment manufacturing and maintenance costs. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 for Figure 1 Enlarged view of A in the middle;
[0018] Figure 3 This is a schematic diagram of the second overall structure of the present invention;
[0019] Figure 4 for Figure 3 Enlarged view of B in the middle;
[0020] Figure 5 This is a partial front sectional view of the present invention;
[0021] Figure 6 for Figure 5 Enlarged view of C;
[0022] Figure 7 This is a schematic diagram of the third overall structure of this utility model;
[0023] Figure 8 This is a partial structural front sectional view of the present invention;
[0024] Figure 9 for Figure 5 Enlarged view of D;
[0025] Reference numerals in the attached drawings: 1. Main body of the equipment; 2. Mounting plate; 3. First air outlet; 4. Support frame; 5. Fixing base; 6. Fixing strip; 7. Second air outlet; 8. Connecting strip; 9. First air inlet duct; 10. Second air inlet duct; 11. Mounting box; 12. Ventilation mesh; 13. First fixing rod; 14. Fan; 15. Air outlet; 16. Compression pipe; 17. Connecting pipe; 18. Exhaust hole; 19. Second fixing rod; 20. Thermoelectric assembly; 21. Temperature sensor. Detailed Implementation
[0026] 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.
[0027] Please see Figures 1-9This utility model proposes an air-cooling device for glass bottle production, comprising a main body 1. Multiple sets of vertically arranged mounting plates 2 are fixedly connected to the inner side of the main body 1, dividing the internal space of the main body 1 into multiple air-cooling zones. A fixed seat 5 is fixedly connected to the top of each air-cooling zone. Fixing strips 6 are fixedly connected between the two sides of the fixed seat 5 and the inner side walls of the main body 1. Both the mounting plates 2 and the fixing strips 6 are hollow structures. A first air outlet 3 is opened on the outside of the mounting plates 2, and a second air outlet 7 is opened on the outside of the fixing strips 6. Multiple sets of equally spaced connecting strips 8 are fixedly connected to the outside of the main body 1, and the connecting strips 8 and fixing strips 6 are matched. An air supply structure is installed between the connecting strips 8, the mounting plates 2, and the fixing strips 6. An installation box 11 is fixedly connected to the rear side of the main body 1. An air-generating structure is installed inside the installation box 11, and an air guide structure is installed between the installation box 11 and the connecting strips 8.
[0028] A support frame 4 is fixedly connected to the upper side of the mounting plate 2. The support frame 4 can be used to place glass bottles that require air cooling.
[0029] The fixing strip 6 is installed at an angle, and the angled design helps to guide the airflow to cover the surface of the glass bottle more evenly.
[0030] The number of first air outlets 3 is several groups arranged in an array, and the number of second air outlets 7 is several groups arranged horizontally. This arrangement ensures that the cold air can be blown evenly to all parts of the glass bottle.
[0031] The air supply structure includes a first air inlet duct 9 and a second air inlet duct 10. The first air inlet duct 9 is located between the mounting plate 2, the main body 1, and the connecting strip 8. The second air inlet duct 10 is located between the fixing strip 6, the main body 1, and the connecting strip 8. The dual air inlet design enables simultaneous cooling of the front and back of the glass bottle.
[0032] The bottom of the mounting box 11 is provided with a ventilation mesh 12, which ensures the circulation of internal air when the fan 14 is working.
[0033] The air-generating structure includes a first fixing rod 13, a fan 14, a second fixing rod 19, and a thermoelectric component 20. The first fixing rod 13 and the second fixing rod 19 are both fixedly connected to the inside of the mounting box 11. The fan 14 is fixedly connected to the outside of the first fixing rod 13. The thermoelectric component 20 is fixedly connected to the outside of the second fixing rod 19. A power supply is fixedly installed inside the mounting box 11, and the power supply is electrically connected to the fan 14 and the thermoelectric component 20. A temperature sensor 21 is fixedly connected inside the mounting box 11.
[0034] The air guiding structure includes an air outlet 15, a compression pipe 16, a connecting pipe 17, and an exhaust hole 18. The air outlet 15 is located on the upper side of the mounting box 11. The compression pipe 16 is fixedly connected to the upper side of the mounting box 11 and completely covers the air outlet 15. The connecting pipe 17 is fixedly connected to the outside of the compression pipe 16, and the connecting pipe 17 is fixedly connected to all the connecting strips 8. The exhaust hole 18 is located between the connecting pipe 17 and the connecting strips 8. This structural design realizes the centralized delivery and uniform distribution of airflow.
[0035] The working principle of an air-cooled device for glass bottle production based on an embodiment is as follows: First, the fired glass bottle is placed on the support frame 4 inside the main body 1 of the equipment. Then, the thermoelectric component 20 in the mounting box 11 is started to preheat the air. At the same time, the fan 14 runs to generate a high-speed airflow. The airflow is first pressurized through the compression pipe 16 of the air guide structure, and then transported to each connecting strip 8 through the connecting pipe 17. Through the exhaust hole 18, the airflow is evenly distributed to the first air inlet duct 9 and the second air inlet duct 10, and injected into the vertically arranged mounting plate 2 and the inclined fixed strip 6 respectively.
[0036] Since both the mounting plate 2 and the fixing strip 6 are hollow, hot air flows inside them and is then sprayed out bidirectionally from the first air outlet 3 arranged in an array on the surface of the mounting plate 2 and the second air outlet 7 arranged horizontally on the fixing strip 6, forming a three-dimensional hot airflow covering the front and back of the glass bottle. During the cooling process, the temperature sensor 21 monitors in real time, and the external processor dynamically adjusts the power of the thermoelectric component 20. Initially, hot air is used to prevent the glass from cracking due to sudden cooling, and then the heat generation is gradually reduced to transition to cold air, achieving a gentle gradient cooling that ensures product integrity and improves cooling efficiency.
[0037] This design uses a single fan 14 in conjunction with a compression pipe 16 for pressurization and a multi-stage diversion channel to precisely deliver airflow to each air-cooled area, replacing the traditional dispersed layout of multiple fans 14. The three-dimensional distribution of the mounting plate 2 and the fixing strip 6 achieves simultaneous cooling on both sides, while the optimized air guide path significantly reduces energy consumption and manufacturing costs. The simplified structure reduces failure points and facilitates maintenance and repair.
[0038] Although embodiments of the present invention 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 to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A wind-cooling device for glass bottle production, characterized in that: The device includes a main body (1), on which multiple sets of vertically arranged mounting plates (2) are fixedly connected. The mounting plates (2) divide the internal space of the main body (1) into multiple air-cooled zones. Each air-cooled zone is fixedly connected to a mounting base (5) at its top. Fixing strips (6) are fixedly connected between the two sides of the mounting base (5) and the two internal side walls of the main body (1). The mounting plates (2) and the fixing strips (6) are hollow structures. A first air outlet is provided on the outside of the mounting plates (2). (3) A second air outlet (7) is provided on the outside of the fixing strip (6). Multiple sets of equally spaced connecting strips (8) are fixedly connected to the outside of the main body of the equipment (1), and the connecting strips (8) and the fixing strips (6) are matched. An air supply structure is installed between the connecting strips (8), the mounting plate (2), and the fixing strips (6). An installation box (11) is fixedly connected to the rear side of the main body of the equipment (1). An air generation structure is installed on the inner side of the installation box (11). An air guide structure is installed between the installation box (11) and the connecting strips (8).
2. The air-cooling device for glass bottle production according to claim 1, characterized in that: A support frame (4) is fixedly connected to the upper side of the mounting plate (2).
3. The air-cooling device for glass bottle production according to claim 1, characterized in that: The fixing strip (6) is installed at an angle.
4. The air-cooling device for glass bottle production according to claim 1, characterized in that: The number of the first air outlet (3) is several groups arranged in an array, and the number of the second air outlet (7) is several groups arranged in a horizontal direction.
5. The air-cooling device for glass bottle production according to claim 1, characterized in that: The air supply structure includes a first air inlet duct (9) and a second air inlet duct (10). The first air inlet duct (9) is located between the mounting plate (2), the equipment body (1) and the connecting strip (8), and the second air inlet duct (10) is located between the fixing strip (6), the equipment body (1) and the connecting strip (8).
6. The air-cooling device for glass bottle production according to claim 1, characterized in that: The bottom of the mounting box (11) is provided with a ventilation mesh (12).
7. The air-cooling device for glass bottle production according to claim 1, characterized in that: The air-generating structure includes a first fixed rod (13), a fan (14), a second fixed rod (19), and a thermoelectric component (20). The first fixed rod (13) and the second fixed rod (19) are both fixedly connected to the inside of the mounting box (11). The fan (14) is fixedly connected to the outside of the first fixed rod (13). The thermoelectric component (20) is fixedly connected to the outside of the second fixed rod (19). A power supply is fixedly installed inside the mounting box (11), and the power supply is electrically connected to the fan (14) and the thermoelectric component (20). A temperature sensor (21) is fixedly connected inside the mounting box (11).
8. The air-cooling device for glass bottle production according to claim 1, characterized in that: The air guiding structure includes an air outlet (15), a compression pipe (16), a connecting pipe (17), and an exhaust hole (18). The air outlet (15) is located on the upper side of the mounting box (11). The compression pipe (16) is fixedly connected to the upper side of the mounting box (11) and completely covers the air outlet (15). The connecting pipe (17) is fixedly connected to the outside of the compression pipe (16) and is fixedly connected to all the connecting strips (8). The exhaust hole (18) is located between the connecting pipe (17) and the connecting strips (8).