An environment-friendly notebook computer shell integrated forming device
Through the design of the temperature control mechanism and the feeding mechanism, the temperature monitoring and feeding of the unibody molding device for environmentally friendly laptop shells have been automated, solving the problem of manual judgment of cooling time in the existing technology, improving production efficiency and reducing costs and breakage rates.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN JILICHENG TECH CO LTD
- Filing Date
- 2025-06-13
- Publication Date
- 2026-06-19
AI Technical Summary
Existing unibody molding machines for environmentally friendly laptop casings lack real-time temperature monitoring capabilities, forcing operators to rely on experience or periodic observation to judge the cooling level of the casing, which affects processing efficiency.
It adopts a temperature control mechanism and a feeding mechanism. The temperature is monitored in real time by an infrared radiation sensor, and the threaded rod and L-shaped pusher are driven by dual drive motors to achieve automated feeding and reduce manual intervention.
It improved production efficiency, reduced production costs, and decreased the probability of material breakage.
Smart Images

Figure CN224372622U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of mold blanking technology, and in particular to an environmentally friendly one-piece molding device for laptop shells. Background Technology
[0002] As an important device for daily office work and entertainment, the manufacturing process of laptops involves not only the selection of materials but also the optimization of production processes.
[0003] Currently, the process of casting and stamping laptop casings is quite complex. Controlling the temperature of the material during casting relies heavily on manual experience. Operators may wait longer before casting to be on the safe side, or they may need to check frequently, which can easily prolong the cycle of a single molding process and reduce the overall efficiency of the production line.
[0004] In some existing technologies, when using unibody molding devices for environmentally friendly laptop casings, there is a lack of a structure that can automatically feed materials based on real-time monitoring of material temperature. This forces operators to rely on experience or periodic observation to determine whether the casing has cooled down properly, which may affect the overall efficiency of the processing. Utility Model Content
[0005] The main purpose of this utility model is to provide an environmentally friendly unibody molding device for laptop shells, which can effectively solve the problem that some existing technologies mentioned above lack a structure that can automatically feed materials based on real-time monitoring of material temperature. This causes operators to rely on experience or periodic observation to judge whether the shell has cooled down properly, which may affect the overall efficiency of the processing.
[0006] To achieve the above objectives, the technical solution adopted by this utility model is as follows:
[0007] An environmentally friendly unibody molding device for laptop casing includes a molding mechanism. Support plates are symmetrically fixedly connected to the middle of the front and rear ends of the outer surface of the molding mechanism. A support mechanism is fixedly connected to the bottom of the two support plates. Temperature control mechanisms are symmetrically fixedly connected to the middle of the left and right ends of the outer surface of the molding mechanism. A feeding mechanism is installed on the lower side of the inner surface of the molding mechanism. A stamping mechanism is installed on the upper side of the molding mechanism.
[0008] Preferably, the molding mechanism includes a lower mold, a bottom pad is slidably connected to the top of the inner surface of the lower mold, and a sliding groove is provided at each of the four corners of the lower mold near the bottom of the bottom pad. Temperature monitoring devices are symmetrically fixedly connected to the middle of the left and right sides of the outer surface of the lower mold.
[0009] Preferably, the inner surfaces of the four slides are all slidably connected with heat insulation pads, and the bottoms of the two heat insulation pads located at the same end are symmetrically fixed with L-shaped pushers. The two L-shaped pushers located on the same side and the lower sides of the opposite sides of the two L-shaped pushers on the other side are jointly fixed with movable seats.
[0010] Preferably, the inner surfaces of the four movable seats are threaded with threaded rods, the upper and lower ends of the threaded rods are fixedly connected with rotating shafts, the outer surfaces of the two rotating shafts are rotatably connected with bearings, and the outer surfaces of the four bearings located on the same side are jointly fixedly connected with an outer frame.
[0011] Preferably, each of the four rotating shafts at the upper end is fixedly connected to a bevel gear one, and the outer surfaces of the two bevel gears one on the same side are symmetrically connected to bevel gears two. The inner surfaces of the two bevel gears two on the same side are fixedly connected to drive shafts, and the outer surfaces of the drive shafts are rotatably connected to bearing supports two. The opposite ends of the two drive shafts on the same side are rotatably connected to a dual drive motor, and the bottom of the dual drive motor is fixedly connected to a motor mounting base.
[0012] Preferably, the bottoms of the two motor mounting bases are respectively fixedly connected to opposite sides of the top of the two outer frames, and control devices are fixedly connected to opposite sides of the top of the two outer frames. The control devices located on the same side are electrically connected to the dual drive motors.
[0013] Preferably, the support mechanism includes a base plate, with support side plates symmetrically fixedly connected to the middle of the top of the base plate, the bottoms of the two outer frames being fixedly connected to the left and right sides of the top of the base plate near the opposite sides of the two support side plates, and the bottoms of the two support plates being fixedly connected to the front and rear sides of the middle of the top of the base plate.
[0014] Preferably, the left and right sides of the outer surface of the stamping mechanism are fixedly connected to the upper sides of the opposite sides of the two support side plates.
[0015] Compared with the prior art, the present invention has the following beneficial effects:
[0016] 1. This device uses a designed temperature control mechanism and a temperature monitoring device to measure the temperature of the lower mold in a non-contact manner, based on the principle of infrared radiation, by receiving infrared radiation emitted from the surface of the object. When the temperature of the outer shell inside the lower mold cools down to the preset range, the temperature monitoring device transmits a signal to the control device. The control device is electrically connected to the dual drive motor, thereby controlling the unloading mechanism to unload and demold the material inside the lower mold. This helps to reduce manual intervention. Through automated unloading, production efficiency can be significantly improved and production costs reduced to a certain extent.
[0017] 2. This device features a designed feeding mechanism that is linked to the temperature control mechanism. Two drive shafts are driven by dual drive motors, which enables the threaded rod and the moving seat to rotate. When the moving seat moves up and down, it can push the L-shaped pusher and the heat insulation pad from the bottom to eject the product, facilitating feeding. The L-shaped pusher is located at the four corners of the bottom of the base plate and can push the product upwards from the four corners simultaneously. By balancing the pressure on the bottom of the base plate, it helps to reduce the probability of material breakage during demolding. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 This is a schematic diagram of the support mechanism structure of this utility model;
[0020] Figure 3 This is a schematic diagram of the molding mechanism structure of this utility model;
[0021] Figure 4 This is a partial cross-sectional view of the molding mechanism of this utility model;
[0022] Figure 5 This is a schematic diagram of the feeding mechanism of this utility model;
[0023] Figure 6 This is a partial structural diagram of the feeding mechanism of this utility model.
[0024] In the diagram: 1. Forming mechanism; 101. Lower mold; 102. Slide groove; 103. Bottom pad; 2. Support plate; 3. Temperature control mechanism; 301. Temperature monitoring device; 302. Control device; 4. Unloading mechanism; 401. L-shaped push frame; 402. Heat insulation pad; 403. Moving seat; 404. Threaded rod; 405. Bearing 1; 406. Rotating shaft; 407. Bevel gear 1; 408. Bevel gear 2; 409. Drive shaft; 410. Bearing support 2; 411. Dual drive motor; 412. Motor mounting base; 413. Outer frame; 5. Stamping mechanism; 6. Support mechanism; 601. Support side plate; 602. Base plate. Detailed Implementation
[0025] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.
[0026] Example 1, as Figure 1As shown, an environmentally friendly laptop shell unibody molding device includes a molding mechanism 1. Support plates 2 are symmetrically fixedly connected to the middle of the front and rear ends of the outer surface of the molding mechanism 1. Support mechanisms 6 are fixedly connected to the bottom of the two support plates 2. Temperature control mechanisms 3 are symmetrically fixedly connected to the middle of the left and right ends of the outer surface of the molding mechanism 1. A feeding mechanism 4 is installed on the lower side of the inner surface of the molding mechanism 1. A stamping mechanism 5 is installed on the upper side of the molding mechanism 1.
[0027] In this embodiment, the temperature monitoring device 301 is installed on the outside of the lower mold 101. The computer shell is stamped by the stamping mechanism 5. Before the product is demolded, the temperature monitoring device 301 uses its non-contact temperature sensor, especially the sensor based on the principle of infrared radiation, to receive the infrared radiation emitted by the surface of the product to measure the temperature, convert it into an electrical signal, and process it through the internal circuit to finally calculate the surface temperature of the object. The temperature data is then transmitted to the control device 302 for analysis through the preset programming of the controller.
[0028] When the temperature drops to the preset range, the control device 302 will control the dual drive motor 411 to drive the two drive shafts 409. Under the rotation of the drive shaft 409 with the bevel gear 408, the two moving seats 403 will rotate with the two threaded rods 404 respectively. By rotating the threaded rods 404 in the forward or reverse direction, the vertical height of the L-shaped push frame moving seat 403 can be adjusted.
[0029] Moving the movable seat 403 upwards allows the product processed inside the lower mold 101 to be pushed out through the L-shaped pusher 401. The heat insulation plate 402 prevents the top of the L-shaped pusher 401 from deforming due to the high temperature of the product, thus affecting the smoothness of the L-shaped pusher 401 sliding up and down inside the heat insulation plate 402. The overall operation is simple and convenient.
[0030] For details, please refer to Figure 1 and Figure 2 In this embodiment, the molding mechanism 1 includes a lower mold 101. A bottom pad 103 is slidably connected to the top of the inner surface of the lower mold 101. Slide grooves 102 are provided at the four corners of the lower mold 101 near the bottom of the bottom pad 103. Temperature monitoring devices 301 are symmetrically fixedly connected to the middle of the left and right sides of the outer surface of the lower mold 101.
[0031] Further reference Figure 1 , Figure 3 and Figure 4In this embodiment, the inner surfaces of the four sliding grooves 102 are all slidably connected with heat insulation pads 402. The bottoms of the two heat insulation pads 402 located at the same end are symmetrically fixed with L-shaped pushers 401. The lower sides of the opposite sides of the two L-shaped pushers 401 on the same side and the two L-shaped pushers 401 on the other side are fixedly connected with movable seats 403.
[0032] Further reference Figure 4 , Figure 5 and Figure 6 In this embodiment, the inner surfaces of the four movable seats 403 are all threaded with threaded rods 404, the upper and lower ends of the threaded rods 404 are fixedly connected with rotating shafts 406, the outer surfaces of the two rotating shafts 406 are rotatably connected with bearings 405, and the outer surfaces of the four bearings 405 located on the same side are jointly fixedly connected with an outer frame 413.
[0033] Further reference Figure 4 , Figure 5 and Figure 6 In this embodiment, bevel gear 407 is fixedly connected to the top of the four rotating shafts 406 at the upper end. Bevel gear 408 is symmetrically connected to the outer surfaces of the two bevel gears 407 on the same side. Drive shaft 409 is fixedly connected to the inner surfaces of the two bevel gears 408 on the same side. Bearing support 410 is rotatably connected to the outer surface of the drive shaft 409. Dual drive motor 411 is rotatably connected to the opposite ends of the two drive shafts 409 on the same side. Motor mounting base 412 is fixedly connected to the bottom of the dual drive motor 411.
[0034] The feeding mechanism 4 is designed to be linked with the temperature control mechanism 3. The two drive shafts 409 are driven by the dual drive motor 411, which achieves the purpose of rotating the threaded rod 404 and the moving seat 403. When the moving seat 403 moves up and down, it can drive the L-shaped pusher 401 and the heat insulation pad 402 to push the product out from the bottom, which facilitates the feeding. The L-shaped pusher 401 is set at the four corners of the bottom of the bottom pad 103. It can push the product upward from the four corners of the bottom at the same time. By balancing the pressure on the bottom of the bottom pad 103, it helps to reduce the probability of material breakage during demolding and feeding.
[0035] Example 2: Based on Example 1, this example adds a control device 302 that monitors the temperature at the lower mold 101 in real time, converts the data, and controls the dual drive motor 411, as well as a support mechanism 6 that supports and fixes the stamping mechanism 5. By setting the temperature control mechanism 3, the material unloading mechanism 4 can automatically unload and demold the material inside the lower mold 101, which helps to reduce manual intervention.
[0036] For details, please refer to Figure 5and Figure 6 In this embodiment, the bottoms of the two motor mounting bases 412 are respectively fixedly connected to the opposite sides of the top of the two outer frames 413. Control devices 302 are fixedly connected to the opposite sides of the top of the two outer frames 413. The control devices 302 located on the same side are electrically connected to the dual drive motors 411.
[0037] Further reference Figure 1 , Figure 2 and Figure 5 In this embodiment, the support mechanism 6 includes a base plate 602, and support side plates 601 are symmetrically fixedly connected to the middle of the top of the base plate 602. The bottoms of the two outer frames 413 are respectively fixedly connected to the left and right sides of the top of the base plate 602 near the opposite sides of the two support side plates 601. The bottoms of the two support plates 2 are respectively fixedly connected to the front and rear sides of the middle of the top of the base plate 602. The left and right sides of the upper surface of the outer surface of the stamping mechanism 5 are respectively fixedly connected to the upper sides of the opposite sides of the two support side plates 601.
[0038] Through the designed temperature control mechanism 3, the temperature monitoring device 301 measures the temperature of the lower mold 101 in a non-contact manner by receiving infrared radiation emitted from the surface of the object based on the principle of infrared radiation. When the temperature of the outer shell inside the lower mold 101 cools down to the preset range, the temperature monitoring device 301 transmits the signal to the control device 302. The control device 302 is electrically connected to the dual drive motor 411, thereby controlling the unloading mechanism 4 to unload and demold the material inside the lower mold 101. This helps to reduce manual intervention. Through automated unloading, production efficiency can be significantly improved and production costs reduced to a certain extent.
[0039] The control device 302 in this solution can be a programmable logic controller in the prior art. It receives the signal from the temperature monitoring device 301 and acts as the "brain" to process the data transmitted by the temperature monitoring device 301. When the temperature is detected to drop to a certain preset threshold, the control system issues an instruction to start the unloading mechanism 4 to unload the product.
[0040] The stamping mechanism 5 in this solution can adopt the existing environmentally friendly integrated stamping equipment for laptop computers. The stamping machine applies pressure to the metal sheet through the mold, causing it to undergo plastic deformation, thereby obtaining parts of a specific shape and size. Based on this, the environmentally friendly integrated stamping equipment for laptop computers further optimizes the process flow and incorporates environmentally friendly designs, such as a dust collection system, to reduce environmental pollution.
[0041] Since it is a very mature product in the existing technology, it will not be described in detail in this application.
[0042] It should be noted that the specific installation method of the drive motor, the circuit connection method, and the control method used in this utility model are all conventional designs, and will not be described in detail here.
[0043] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claims. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. An environment-friendly notebook computer shell integrated forming device, comprising a forming mechanism (1), characterized in that: The forming mechanism (1) has a support plate (2) fixedly connected symmetrically at the front and rear ends of the outer surface. The two support plates (2) are fixedly connected together at the bottom of the support mechanism (6). The forming mechanism (1) has a temperature control mechanism (3) fixedly connected symmetrically at the middle of the left and right ends of the outer surface. The forming mechanism (1) has a feeding mechanism (4) installed on the lower side of the inner surface. The forming mechanism (1) has a stamping mechanism (5) installed on the upper side.
2. The integrally formed device of an environmentally friendly notebook computer shell according to claim 1, wherein: The molding mechanism (1) includes a lower mold (101), and a bottom pad (103) is slidably connected to the top of the inner surface of the lower mold (101). Slide grooves (102) are provided at the four corners of the lower mold (101) near the bottom of the bottom pad (103). Temperature monitoring devices (301) are symmetrically fixedly connected to the middle of the left and right sides of the outer surface of the lower mold (101).
3. The integrally formed device of an environmentally friendly notebook computer shell according to claim 2, wherein: The inner surfaces of the four slides (102) are all slidably connected with heat insulation pads (402). The bottoms of the two heat insulation pads (402) located at the same end are symmetrically fixed with L-shaped pushers (401). The two L-shaped pushers (401) located on the same side and the lower sides of the opposite sides of the two L-shaped pushers (401) on the other side are fixedly connected with movable seats (403).
4. The integrally formed device of an environmentally friendly notebook computer shell according to claim 3, wherein: The inner surfaces of the four movable seats (403) are threaded with threaded rods (404), and the upper and lower ends of the threaded rods (404) are fixedly connected with rotating shafts (406). The outer surfaces of the two rotating shafts (406) are rotatably connected with bearings (405). The outer surfaces of the four bearings (405) located on the same side are fixedly connected with an outer frame (413).
5. The integrally formed device of an environmentally friendly notebook computer shell according to claim 4, wherein: The top of each of the four rotating shafts (406) at the upper end is fixedly connected to a bevel gear (407). The outer surfaces of the two bevel gears (407) on the same side are symmetrically connected to a bevel gear (408). The inner surfaces of the two bevel gears (408) on the same side are fixedly connected to a drive shaft (409). The outer surface of the drive shaft (409) is rotatably connected to a bearing support (410). The opposite ends of the two drive shafts (409) on the same side are rotatably connected to a dual drive motor (411). The bottom of the dual drive motor (411) is fixedly connected to a motor mounting base (412).
6. The integrally formed device of an environmentally friendly notebook computer shell according to claim 5, wherein: The bottoms of the two motor mounting bases (412) are respectively fixedly connected to the opposite sides of the top of the two outer frames (413). Control devices (302) are fixedly connected to the opposite sides of the top of the two outer frames (413). The control devices (302) located on the same side are electrically connected to the dual drive motors (411).
7. The integrally formed device of an environmentally friendly notebook computer shell according to claim 1, wherein: The support mechanism (6) includes a base plate (602), and support side plates (601) are symmetrically fixedly connected to the middle of the top of the base plate (602). The bottoms of the two outer frames (413) are respectively fixedly connected to the left and right sides of the top of the base plate (602) near the opposite sides of the two support side plates (601). The bottoms of the two support plates (2) are respectively fixedly connected to the front and rear sides of the middle of the top of the base plate (602).
8. The environmentally friendly laptop casing unibody molding device according to claim 1, characterized in that: The left and right sides of the outer surface of the stamping mechanism (5) are respectively fixedly connected to the upper sides of the opposite sides of the two support side plates (601).