Intelligent control cabinet special for grain and oil system
By installing a square steel frame and a fan inside the control cabinet, the problem of low cooling efficiency in existing control cabinets is solved, achieving more efficient cooling of electrical components and convenient wiring and maintenance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHENGZHOU GOLDENGRAIN EQUIP ENG CO LTD
- Filing Date
- 2025-03-18
- Publication Date
- 2026-06-12
AI Technical Summary
The existing control cabinet has poor cooling efficiency of the fan and low heat exchange efficiency between the airflow and electrical components.
A square steel frame is installed inside the control cabinet. A through hole is made in the square steel frame, and a fan is installed on the cabinet. The fan blows air towards the middle of the square steel tube to accelerate air circulation. The airflow flows out through the through hole and exchanges heat with the electrical components.
It improves the cooling effect of electrical components, significantly enhances the heat exchange efficiency between airflow and electrical components, increases structural strength, and facilitates wiring and maintenance.
Smart Images

Figure CN224355687U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of control cabinets, and in particular to an intelligent control cabinet specifically designed for grain and oil systems. Background Technology
[0002] A control cabinet is a device that houses switchgear, measuring instruments, and electrical equipment in a closed or semi-closed metal cabinet according to electrical wiring requirements. Its layout should meet the requirements for normal operation of the power system, facilitate maintenance, and not endanger the safety of personnel and surrounding equipment.
[0003] The control cabinet contains numerous electrical devices, which generate significant heat when powered on, resulting in a high temperature inside the cabinet. Existing control cabinets are equipped with fans to accelerate airflow inside and outside the cabinet, thereby cooling the electrical components and lowering their operating temperature.
[0004] The aforementioned technical solutions have the following drawbacks: the airflow generated by the fan has poor efficiency in exchanging heat with electrical components inside the control cabinet, resulting in poor cooling efficiency of the fan. Utility Model Content
[0005] In order to improve the efficiency of cooling the electrical components in the control cabinet, this application provides a special intelligent control cabinet for grain and oil systems.
[0006] The technical solution for a dedicated intelligent control cabinet for grain and oil systems provided in this application is as follows:
[0007] A special intelligent control cabinet for grain and oil systems includes a cabinet body, a cabinet door, and a mounting frame. The cabinet door is rotatably connected to the cabinet body. The mounting frame includes a square steel frame, which is formed by splicing square steel pipes together. The square steel frame is set inside the cabinet body. Multiple through holes are opened along the length of the square steel pipes. A fan is installed on the cabinet body, and the fan is oriented towards the square steel pipes.
[0008] By adopting the above technical solution, a square steel frame is installed in the cabinet, and multiple square steels are connected to form a frame structure. This allows the square steel frame to support the cabinet and improve its structural strength. Multiple through holes are opened in the square steel frame, allowing the wires of electrical components to be inserted into the through holes, facilitating the wiring of the electrical components inside the cabinet. A fan is installed in the cabinet to accelerate the air circulation inside and outside the cabinet. When the fan is started, it blows air towards the middle of the square steel tube, allowing the airflow to circulate inside the square steel tube and flow out through the through holes. This results in a high efficiency of heat exchange between the airflow and the electrical components, and a better cooling effect on the electrical components.
[0009] Optionally, a slide rail is installed at the bottom of the cabinet, and a square steel frame is slidably connected to the slide rail.
[0010] By adopting the above technical solution, and by setting slide rails inside the cabinet, the square steel frame is slidably connected in the slide rails. The square steel frame can slide towards the opening side of the cabinet, which facilitates the installation and maintenance of electrical components on the square steel frame by users.
[0011] Optionally, a base plate is provided on the square steel frame, and the base plate is used to mount electrical components.
[0012] By adopting the above technical solution, and by setting a base plate on the square steel frame, more electrical components can be installed on the base plate. Users can place the electrical components in the area enclosed by the square steel pipe, thereby improving the cooling efficiency of the fan.
[0013] Optionally, the substrate is provided with a clip frame for engaging with electrical components.
[0014] By adopting the above technical solution, and by setting a frame on the substrate, electrical components can be clipped into the frame and slide along the length of the frame, thereby facilitating the user to set multiple electrical components along the length of the frame and improving installation efficiency.
[0015] Optionally, a wire frame is provided inside the square steel frame, which is used to bind and fix the wires.
[0016] By adopting the above technical solution, and by setting a wire frame inside the square steel frame, when the wires on the electrical components are inserted into the through holes, the wires can be fixed to the wire frame by binding, thereby reducing the swaying of the wires inside the square steel frame and allowing the airflow generated by the fan to flow smoothly inside the square steel frame.
[0017] Optionally, an exhaust fan is installed on the cabinet door, which runs through and is fixed to the cabinet door.
[0018] By adopting the above technical solution, an exhaust fan is installed on the cabinet door to extract the air from the cabinet, thereby ensuring smooth air circulation inside the cabinet.
[0019] Optionally, sensors are installed inside the cabinet door to detect environmental parameters inside the cabinet.
[0020] By adopting the above technical solution and installing sensors inside the cabinet door, the sensors can detect data such as temperature and humidity inside the cabinet, thereby facilitating users to check the working status of electrical components inside the cabinet and making maintenance easier.
[0021] Optionally, a display panel is installed on the outer surface of the cabinet door, and the display panel is electrically connected to the sensor.
[0022] By adopting the above technical solution and installing a display panel on the outside of the cabinet door, users can view the temperature and humidity inside the cabinet through the display panel. The display panel can also display information such as the working status of electrical components inside the cabinet, making it convenient to use and reducing the steps required for users to open the cabinet door and check.
[0023] In summary, the beneficial technical effects of this application are as follows:
[0024] 1. By setting up a square steel frame in the cabinet, multiple square steels are connected to form a frame structure, which supports the cabinet and improves the structural strength of the cabinet. By opening multiple through holes in the square steel frame, the wires of electrical components can be inserted into the through holes, which is convenient for users to lay wires in the cabinet. By installing a fan in the cabinet, the fan can accelerate the air circulation inside and outside the cabinet. When the fan is started, the fan blows air towards the middle of the square steel tube, which allows the airflow to flow in the square steel tube and out through the through holes. This results in a high efficiency of heat exchange between the airflow and the electrical components, and a better cooling effect on the electrical components.
[0025] 2. By setting a wire frame inside the square steel frame, when the wires on the electrical components are inserted into the through holes, the wires can be fixed to the wire frame by binding, thereby reducing the swaying of the wires inside the square steel frame and allowing the airflow generated by the fan to flow smoothly inside the square steel frame.
[0026] 3. By installing a display panel on the outside of the cabinet door, users can view the temperature and humidity inside the cabinet. The display panel can also show information such as the working status of electrical components inside the cabinet, making it convenient to use and reducing the steps required for users to open the cabinet door and check. Attached Figure Description
[0027] Figure 1 This is a schematic diagram of the overall structure of an embodiment of this application.
[0028] Figure 2 This is a schematic diagram of the mounting bracket according to an embodiment of this application.
[0029] Figure 3 This is a schematic diagram of the steel wire frame according to an embodiment of this application.
[0030] Figure 4 This is a schematic diagram showing the position of the sensor in an embodiment of this application.
[0031] Reference numerals: 1. Cabinet; 2. Cabinet door; 21. Exhaust fan; 22. Sensor; 23. Display panel; 3. Mounting bracket; 31. Square steel frame; 311. Through hole; 32. Base plate; 321. Card frame; 322. Waist hole; 33. Slide rail; 34. Wire frame; 4. Fan. Detailed Implementation
[0032] The present application will be further described in detail below with reference to the accompanying drawings.
[0033] This application discloses a dedicated intelligent control cabinet for grain and oil systems, referring to... Figure 1 , Figure 2 and Figure 3 The system includes a cabinet body 1, a cabinet door 2, and a mounting frame 3. The cabinet door 2 is rotatably connected to the cabinet body 1. The mounting frame 3 is set inside the cabinet body 1 and includes multiple square steel frames 31. The square steel frames 31 are formed by splicing square steel pipes. The square steel frames 31 support the cabinet body 1 inside the cabinet body 1 and improve the overall structural strength of the cabinet body 1. Multiple through holes 311 are opened on the square steel frames 31. The through holes 311 are spaced apart along the length of the square steel. When users install electrical components inside the cabinet body 1, the wires on the electrical components can be inserted into the through holes 311, which facilitates the wiring inside the cabinet body 1.
[0034] Reference Figure 1 , Figure 2 and Figure 3 The interconnected square steel frames 31 are connected by through holes 311. An air inlet is provided on the cabinet 1, and a fan 4 is installed on the cabinet 1, embedded in the air inlet. When the mounting bracket 3 is placed inside the cabinet 1, the fan 4 blows air towards the center of the square steel tube, causing the airflow to exit through the through holes 311, thus cooling the electrical components. The fan 4 provides air cooling, injecting low-temperature airflow from outside the cabinet 1 into the cabinet 1. The airflow within the cabinet 1 is more uniform and directed towards the electrical components, thereby improving the cooling effect on the electrical components inside the cabinet 1.
[0035] Reference Figure 1 , Figure 2 and Figure 3 A base plate 32 is mounted on the square steel frame 31. The base plate 32 is vertically mounted and fixed to one side of the square steel frame 31, and the base plate 32 is attached to the back panel of the cabinet 1. The base plate 32 is used to install electrical components. When the electrical components are mounted on the base plate 32, the square steel frame 31 is located on one side of the electrical components, and the through hole 311 on the square steel frame 31 faces the electrical components.
[0036] Reference Figure 1 , Figure 2 and Figure 3 The substrate 32 is provided with a frame 321, which is a slide rail structure. Electrical components are snapped into the frame 321, so that the electrical components can be easily and quickly installed on the substrate 32. The frame 321 has multiple slots 322, which are used to install bolts. The electrical components are fixed to the substrate 32 by bolts, which can improve the positional stability of the electrical components on the substrate 32.
[0037] Reference Figure 2A slide rail 33 is installed on the bottom of the cabinet 1, and the bottom of the square steel frame 31 is slidably connected to the slide rail 33. The length direction of the slide rail 33 faces the opening of the cabinet 1. Users can slide the mounting bracket 3 along the slide rail 33, which facilitates the inspection and maintenance of electrical components on the circuit board 32.
[0038] Reference Figure 3 A steel wire frame 34 is installed inside the square steel frame 31. The steel wire frame 34 is mounted on the base plate 32 and is perpendicular to the base plate 32. An opening is opened on the square steel tube to form a frame structure, and the square steel tube covers the steel wire frame 34. When the wire of the electrical component is inserted into the through hole 311, the wire of the electrical component can be fixed to the steel wire frame 34 by binding, further improving the convenience of wiring in the cabinet 1.
[0039] Reference Figure 4 An exhaust fan 21 is installed on the cabinet door 2, passing through and fixed to the cabinet door 2. The exhaust fan 21 is used to exhaust the air inside the cabinet 1. A sensor 22 is installed on the cabinet door 2, located on the side of the cabinet door 2 close to the inside of the cabinet 1. The sensor 22 can be a temperature sensor or a humidity sensor. The sensor 22 is used to detect the environmental parameters inside the cabinet 1. A display panel 23 is installed on the cabinet door 2, mounted on the outer surface of the cabinet door 2. The display panel 23 is electrically connected to the sensor 22 and can display the detection data of the sensor 22, thereby facilitating the user to inspect and repair the electrical components inside the cabinet 1.
[0040] The implementation principle of this application embodiment is as follows: By setting a mounting bracket 3 inside the cabinet 1, electrical components are placed on the base plate 32, thereby enabling the square steel frame 31 to support the cabinet 1 and protect the electrical components. By opening multiple through holes 311 on the square steel frame 31, the wires on the electrical components can be inserted into the through holes 311, thereby facilitating the installation of wires by users in the cabinet 1 and simplifying the structure. By setting a fan 4 on the cabinet 1, the fan 4 promotes air circulation inside and outside the cabinet 1. The airflow generated by the fan 4 blows towards the electrical components through the through holes 311, further enhancing the cooling effect on the electrical components inside the cabinet 1.
[0041] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. A special intelligent control cabinet for grain and oil systems, characterized in that: The cabinet includes a cabinet body (1), a cabinet door (2), and a mounting frame (3). The cabinet door (2) is rotatably connected to the cabinet body (1). The mounting frame (3) includes a square steel frame (31). The square steel frame (31) is formed by splicing square steel pipes together. The square steel frame (31) is set inside the cabinet body (1). Multiple through holes (311) are opened along the length direction on the square steel pipes. The square steel frames (31) connected to each other are connected through the through holes (311). The through holes (311) on the square steel frame (31) face the electrical components. A fan (4) is set on the cabinet body (1). The fan (4) is set towards the cavity in the middle of the square steel pipe.
2. The intelligent control cabinet for a grain and oil system according to claim 1, characterized in that: The cabinet (1) is equipped with a slide rail (33) at the bottom, and the square steel frame (31) is slidably connected to the slide rail (33).
3. The intelligent control cabinet for a grain and oil system according to claim 2, characterized in that: A base plate (32) is provided on the square steel frame (31), and the base plate (32) is used to install electrical components.
4. The intelligent control cabinet for a grain and oil system according to claim 3, characterized in that: The substrate (32) is provided with a frame (321) for engaging with electrical components.
5. The intelligent control cabinet for a grain and oil system according to claim 1, characterized in that: The square steel frame (31) is equipped with a wire frame (34), which is used to bind and fix the wires.
6. The intelligent control cabinet for a grain and oil system according to claim 1, characterized in that: An exhaust fan (21) is installed on the cabinet door (2), and the exhaust fan (21) passes through and is fixed on the cabinet door (2).
7. The intelligent control cabinet for a grain and oil system according to claim 1, characterized in that: A sensor (22) is installed on the inside of the cabinet door (2). The sensor (22) is used to detect environmental parameters inside the cabinet (1).
8. The intelligent control cabinet for a grain and oil system according to claim 7, characterized in that: A display panel (23) is provided on the outer side of the cabinet door (2), and the display panel (23) is electrically connected to the sensor (22).