Energy supply power generation device

By designing an automatic refueling system for power generation equipment, the problems of high manual labor intensity and high risk of oil leakage in the fuel replenishment process of diesel generator sets have been solved, realizing automated, stable and safe fuel replenishment and ensuring the continuous operation of the equipment.

CN224379961UActive Publication Date: 2026-06-19HONGYUN HONGHE TOBACCO (GRP) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HONGYUN HONGHE TOBACCO (GRP) CO LTD
Filing Date
2025-06-24
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In remote tobacco factories, the fuel replenishment process for diesel generator sets is characterized by high manual labor intensity, a high risk of oil leaks, and numerous safety hazards. In particular, it is difficult to quickly obtain fuel during sudden power outages, which affects equipment operation.

Method used

A power generation device was designed, including a base plate, a fuel-fired power generation module, a refueling module, and a pipeline positioning module. The device automatically refuels the oil pipes using an oil pump and clamping components to prevent the oil pipes from dragging and bending. The combination of clamping components and a lifting seat enables stable clamping and dynamic adjustment of the oil pipes.

Benefits of technology

It has achieved automated fuel replenishment, reduced labor intensity, prevented oil leaks, ensured a smooth and safe refueling process, and improved the operational stability and safety of the equipment.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224379961U_ABST
    Figure CN224379961U_ABST
Patent Text Reader

Abstract

This utility model discloses a power generation device, belonging to the field of tobacco processing technology. The power generation device includes a base plate, a fuel-fired power generation module, a refueling module, and a pipeline positioning module. The fuel-fired power generation module includes a generator and a fuel tank mounted on the base plate. The refueling module has a fuel tank mounted on the base plate, with one end of the fuel pipe connected to the fuel tank and the other end connected to the fuel container. A fuel pump is mounted on the base plate and connected to the middle section of the fuel pipe. The pipeline positioning module includes a first reinforcement unit, which includes a guide rail, a lifting seat, and a first clamping assembly. The guide rail is mounted on the base plate, the lifting seat is mounted on the guide rail and can slide along a first direction, and the first clamping assembly is mounted on the lifting seat. The first clamping assembly is used to clamp the fuel pipe and can lift it along the first direction. This utility model can refuel diesel generator sets and avoids dragging and bending of the fuel pipeline, facilitating a smooth refueling process.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of tobacco processing technology, and in particular to a power generation device. Background Technology

[0002] With the continuous development of the social economy and the increasing demands for stable power supply in industrial production, the need for reliable power supply for critical equipment in the unique industrial setting of tobacco factories is becoming increasingly prominent. Due to the special nature of tobacco factories in industrial layout, they are often located in relatively remote areas. This geographical feature results in relatively weak infrastructure around the factories, especially their distance from regular gas stations. These geographical limitations make it difficult for tobacco factories to quickly obtain fuel supplies from external sources in the event of sudden power outages or other power supply disruptions, thus posing a potential threat to the continuous operation of critical internal equipment.

[0003] Under current technological conditions, diesel generator sets are often used as the primary source of power to address emergency power needs in tobacco factories in remote areas. However, in practice, the fuel replenishment process for diesel generator sets faces numerous challenges. Traditionally, factories have relied on manual refueling by manually operating the fuel lines to fill the diesel generator sets' tanks. This process requires operators to precisely connect the fuel lines to the tanks and possess sufficient physical strength and endurance to withstand prolonged, high-intensity physical labor.

[0004] However, in reality, manual refueling not only significantly increases the intensity of manual labor, making operators prone to fatigue and errors, but also greatly increases the risk of oil leaks during the connection process. Oil leaks not only directly waste energy and increase production costs, but more importantly, if leaked fuel comes into contact with high-temperature components or ignition sources, it can easily cause fires and other safety accidents, posing a serious threat to the safety of equipment and personnel within the factory. Furthermore, because oil pipelines are prone to bending and dragging under gravity, this further exacerbates the risk of incomplete connections and loosening, making the refueling process unsmooth and potentially triggering a chain reaction of oil leaks, further deteriorating the safe production environment.

[0005] This section provides background information related to this application, which is not necessarily prior art. Utility Model Content

[0006] The purpose of this invention is to provide a power generation device that can automatically refuel diesel generator sets and prevent oil pipelines from dragging and bending, thus facilitating a smooth refueling process.

[0007] To achieve the above objectives, the following technical solution is provided:

[0008] Power generation equipment, including:

[0009] Base plate;

[0010] A fuel-fired power generation module includes a generator and a fuel tank mounted on the base plate, wherein the generator is connected to the fuel tank;

[0011] A refueling module includes an oil tank, an oil pipe body, and an oil pump. The oil tank is mounted on the base plate. One end of the oil pipe body is connected to the oil tank, and the other end of the oil pipe body is connected to the oil tank. The oil pump is mounted on the base plate and connected to the middle section of the oil pipe body.

[0012] The pipeline positioning module includes a first reinforcement unit disposed between the oil pump and the oil tank. The first reinforcement unit includes a guide rail, a lifting seat, and a first clamping assembly. The guide rail is disposed on the base plate, the lifting seat is disposed on the guide rail and can slide along a first direction, and the first clamping assembly is disposed on the lifting seat. The first clamping assembly is used to clamp the oil pipe body and can be lifted along the first direction.

[0013] As an optional power generation device, the lifting seat is provided with two fixing bars on the side near the oil pipe body, the fixing bars extending along a second direction, and the first clamping assembly includes:

[0014] Two first rotating jaws are rotatably mounted on the corresponding fixed bar. One end of the first rotating jaw is provided with a first sliding groove, and the other end of the first rotating jaw is used to abut against the oil pipe body.

[0015] A first cylinder with a drive shaft is disposed on the lifting seat. The drive shaft passes through the first groove of the two first rotating jaws. The first cylinder is used to drive the two first rotating jaws to rotate and clamp or release the oil pipe body.

[0016] As an optional solution for power generation equipment, the first clamping assembly further includes:

[0017] Two first semi-circular clips are provided at the other end of the corresponding first rotating jaws, and the first arc groove of one of the first semi-circular clips is arranged opposite to the first arc groove of the other first semi-circular clip.

[0018] As an optional solution for power generation equipment, the first reinforcement unit further includes a lifting drive mechanism, which is disposed on the base plate. The output end of the lifting drive mechanism is connected to the lifting seat in a transmission manner, and the lifting drive mechanism is used to drive the lifting seat to move along the first direction.

[0019] As an optional solution for power generation equipment, the pipeline positioning module also includes a second reinforcement unit. The second reinforcement unit includes a fixing plate and a second clamping assembly. The fixing plate is located on the top of the oil tank and near the oil inlet. The second clamping assembly is located on the fixing plate and is used to clamp or release the oil pipe body.

[0020] As an optional solution for power generation equipment, the second clamping assembly includes:

[0021] Two second rotating jaws are rotatably mounted on the fixed plate. One end of the second rotating jaw is fixedly mounted with a pin, and the other end of the second rotating jaw is used to abut against the oil pipe body.

[0022] A connecting plate is located between the two second rotating jaws and can move in a third direction. The two ends of the connecting plate are respectively provided with second sliding grooves, and the pin passes through the second sliding grooves. The connecting plate is used to drive the two second rotating jaws to clamp or loosen the oil pipe body.

[0023] As an optional solution for power generation equipment, the second clamping assembly further includes:

[0024] A second cylinder is mounted on the fixed plate, and the piston rod of the second cylinder is connected to the connecting plate. The second cylinder is used to drive the connecting plate to move along the third direction.

[0025] As an optional solution for power generation equipment, the second clamping assembly further includes:

[0026] Two second semi-circular sleeves are provided at the other end of the corresponding second rotating jaws, and the second arc groove of one of the second semi-circular sleeves is arranged opposite to the second arc groove of the other second semi-circular sleeve.

[0027] As an optional solution for power generation equipment, the pipeline positioning module also includes a third reinforcement unit located between the oil pump and the oil tank. The third reinforcement unit includes a support rod, the bottom of which is connected to the base plate, and the top of which abuts against the main body of the oil pipe.

[0028] As an optional solution for power generation equipment, the third reinforcement unit also includes a third semi-circular jacket, which is disposed on the support rod, and the third arc-shaped groove of the third semi-circular jacket abuts against the oil pipe body.

[0029] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0030] The power generation equipment provided by this utility model has a fuel-fired power generation module installed in the first placement area of ​​the base plate, and a refueling module installed in the second placement area of ​​the base plate. One end of the fuel pipe of the refueling module is connected to the fuel tank, and the other end is connected to the fuel container. The fuel pump delivers fuel from the fuel tank of the refueling module to the fuel container of the fuel-fired power generation module via the fuel pipe, meeting the generator's fuel supply needs. This eliminates the need for manual refueling, reducing labor intensity and preventing fuel leaks. For the fuel pipe between the pump and the container, a first clamping assembly clamps the fuel pipe. A lifting seat moves along a guide rail in a first direction, lifting the fuel pipe upwards to prevent it from dragging and bending, thus facilitating a smooth refueling process. Attached Figure Description

[0031] To more clearly illustrate the technical solutions in the embodiments of this utility model, the drawings used in the description of the embodiments of this utility model will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the content of the embodiments of this utility model and these drawings without creative effort.

[0032] Figure 1 This is a first-view assembly diagram of the power generation equipment in an embodiment of this utility model.

[0033] Figure 2 for Figure 1 A magnified view of a portion of point A in the middle;

[0034] Figure 3 This is a second-view assembly diagram of the power generation equipment in an embodiment of this utility model.

[0035] Figure 4 for Figure 3 A magnified view of a portion of point B in the middle;

[0036] Figure 5 This is a schematic diagram of the connecting plate in an embodiment of the present utility model.

[0037] Figure label:

[0038] 1. Base plate; 2. Fuel-fired power generation module; 3. Refueling module; 4. First reinforcement unit; 5. Second reinforcement unit; 6. Third reinforcement unit;

[0039] 21. Generator; 22. Fuel tank;

[0040] 31. Oil tank; 32. Oil pipeline body; 33. Oil pump;

[0041] 41. Guide rail; 42. Lifting seat; 43. Fixing bar; 44. First rotating gripper; 441. First slide groove; 45. Drive shaft; 46. First cylinder; 47. First semi-circular sleeve; 471. First arc groove;

[0042] 51. Fixed plate; 52. Second rotating gripper; 53. Pin; 54. Connecting plate; 541. Second sliding groove; 55. Second cylinder; 56. Second semi-circular sleeve; 561. Second arc-shaped groove;

[0043] 61. Support rod; 62. Third semi-circular sleeve; 621. Third arc-shaped groove. Detailed Implementation

[0044] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. The components of the embodiments of this utility model described and shown in the accompanying drawings can generally be arranged and designed in various different configurations.

[0045] In the description of this utility model, it should be noted that the terms "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, or the orientation or positional relationship commonly used when the product of this utility model is in use. They are used only for the convenience of describing this utility model and for 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. Furthermore, the terms "first," "second," and "third," etc., are used only to distinguish descriptions and should not be construed as indicating or implying relative importance. In the description of this utility model, unless otherwise stated, "a plurality of" means two or more.

[0046] In the description of this utility model, it should also be noted that, unless otherwise explicitly specified and limited, the terms "set" and "connection" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.

[0047] The embodiments of this utility model are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain this utility model, and should not be construed as limiting this utility model.

[0048] To enable automatic refueling of diesel generator sets and prevent fuel pipelines from dragging and bending, thus facilitating a smooth refueling process, this embodiment provides a power generation device, which is described below in conjunction with... Figures 1 to 5 The specific content of this embodiment will be described in detail. It should be noted that the first direction mentioned in this embodiment is... Figure 1 The Z direction in this embodiment, and the second direction mentioned in this embodiment are Figure 1 In the Y direction, the third direction mentioned in this embodiment is Figure 1 The X direction in the equation.

[0049] like Figures 1 to 4As shown, the carefully designed power generation equipment in this embodiment integrates four core components: a base plate 1, a fuel-fired power generation module 2, a refueling module 3, and a pipeline positioning module, forming a highly efficient, stable, and safe energy supply system. The fuel-fired power generation module 2 serves as the power source for the entire system. It comprises a generator 21 and a fuel tank 22, both securely mounted on the base plate 1. These are tightly connected via a sophisticated piping system, ensuring a smooth and unobstructed flow of fuel from the fuel tank 22 to the generator 21. During this process, the fuel tank 22 not only serves as a fuel storage container but also plays a crucial role in efficiently converting the chemical energy of the fuel into electrical energy, providing continuous power support for subsequent equipment. The refueling module 3 is a vital guarantee for the fuel replenishment of the entire system. It consists of three main components: a fuel tank 31, a fuel pipeline body 32, and a fuel pump 33, forming a complete fuel delivery network. The fuel tank 31 is properly positioned on the base plate 1 as the initial storage location for the fuel. The main body of the oil pipe 32 acts as a lifeline, with one end tightly connected to the oil tank 31 and the other end extending to the fuel tank 22, responsible for transporting fuel from the oil tank 31 to the fuel tank 22. The oil pump 33, as the power heart of this transport process, is mounted on the base plate 1 and connected to the middle section of the oil pipe 32. Its powerful suction capacity ensures efficient and stable delivery of fuel to the fuel tank 22. The pipeline positioning module is a major innovative highlight of this embodiment. The pipeline positioning module includes a first reinforcing unit 4 positioned between the oil pump 33 and the fuel tank 22. This first reinforcing unit 4 is precisely composed of a guide rail 41, a lifting seat 42, and a first clamping assembly. The guide rail 41, serving as the moving track for the lifting seat 42, is securely mounted on the base plate 1. The lifting seat 42, like a flexible robotic arm, can slide freely along the guide rail 41 in the first direction, achieving precise position adjustment. The first clamping component, like a precise robotic hand, is cleverly positioned on the lifting seat 42 to clamp the oil pipe body 32 and perform a lifting operation along the first direction. This design not only effectively prevents the oil pipe body 32 from dragging and bending under gravity, but also achieves dynamic adjustment of the oil pipe body 32 through the movement of the lifting seat 42, ensuring a smooth refueling process.

[0050] The power generation equipment provided by this utility model features a scientifically and rationally divided area on the base plate 1. The first placement area houses the fuel-powered generator module 2, while the second placement area houses the refueling module 3. One end of the refueling module 3's oil pipe body 32 is connected to the oil tank 31, and the other end is connected to the fuel tank 22. Through the powerful working capacity of the oil pump 33, fuel from the refueling module 3's oil tank 31 is precisely delivered through the oil pipe body 32 to the fuel tank 22 of the fuel-powered generator module 2, thus meeting the urgent fuel supply needs of the generator 21. This design completely eliminates the traditional manual refueling method, significantly reducing labor intensity and fundamentally preventing oil leaks, providing strong protection for the safe operation of the equipment. More notably, this embodiment uses a first clamping assembly to clamp and fix the oil pipe body 32 between the oil pump 33 and the fuel tank 22, and the upward lifting operation of the oil pipe body 32 is achieved through the flexible movement of the lifting seat 42 on the guide rail 41. This innovative design not only effectively avoids the bending of the main body of the oil pipe 32 due to dragging on the ground, but also ensures a smooth refueling process through dynamic adjustment, laying a solid foundation for the efficient operation of the entire power supply and generation equipment.

[0051] Furthermore, such as Figure 1 Combination Figure 2As shown, the lifting seat 42 has two fixing bars 43 on the side near the oil pipe body 32. The fixing bars 43 extend along the second direction. The first clamping assembly includes a first cylinder 46 with a drive shaft 45 and two first rotating jaws 44. The first rotating jaws 44 are rotatably mounted on the corresponding fixing bars 43. One end of the first rotating jaw 44 is provided with a first sliding groove 441, and the other end of the first rotating jaw 44 is used to abut against the oil pipe body 32. The first cylinder 46 is mounted on the lifting seat 42, and the drive shaft 45 passes through the first sliding grooves 441 of the two first rotating jaws 44. The piston rod of the first cylinder 46 can drive the drive shaft 45 to move along the second direction. The first cylinder 46 is used to drive the two first rotating jaws 44 to rotate and clamp or release the oil pipe body 32. The first rotating jaws 44 are rotatably mounted on the corresponding fixing bars 43. This design allows the jaws to flexibly adjust their angle to adapt to oil pipes at different positions and angles. Each first rotating jaw 44 has a first groove 441 at one end. The first groove 441 not only provides space for the drive shaft 45 to move, but also ensures the stability and accuracy of the drive shaft 45 during movement through its specific shape and size. The other end of the first rotating jaw 44 is designed to abut against the oil pipe body 32. In this clamping state, the first rotating jaw 44 can closely fit the surface of the oil pipe, providing sufficient clamping force to ensure the stability of the oil pipe during the refueling process. The first cylinder 46, as the power source for driving the rotation of the first rotating jaw 44, is firmly mounted on the lifting seat 42. Its drive shaft 45 passes through the first grooves 441 of the two first rotating jaws 44. Through the extension and retraction of the first cylinder 46, the drive shaft 45 can move within the first grooves 441, driving the two first rotating jaws 44 to rotate synchronously. When the first cylinder 46 operates, the drive shaft 45 moves in one direction, pushing the two first rotating jaws 44 closer together and clamping the oil pipe body 32. When the first cylinder 46 operates in the opposite direction, the drive shaft 45 moves in the opposite direction, causing the two first rotating jaws 44 to move away from each other and release the oil pipe body 32. Through this design, the power generation equipment in this embodiment achieves precise clamping and releasing operations on the oil pipe body 32. During refueling, when fuel needs to be delivered to the fuel tank 22, the first cylinder 46 drives the two first rotating jaws 44 to clamp the oil pipe body 32, ensuring that the oil pipe body 32 will not shake or fall off due to external forces during refueling, thereby ensuring the stability and safety of the refueling process. After refueling is completed, the first cylinder 46 then drives the two first rotating jaws 44 to release the oil pipe body 32, facilitating the disassembly and replacement of the oil pipe.

[0052] Furthermore, such as Figure 2As shown, the first clamping assembly also includes two first semi-circular sleeves 47. The first semi-circular sleeves 47 are disposed at the other end of the corresponding first rotating jaws 44. The first arc-shaped groove 471 of one of the first semi-circular sleeves 47 is opposite to the first arc-shaped groove 471 of the other first semi-circular sleeve 47. The two first arc-shaped grooves 471 are used to adapt to the outer wall surface of the tubing body 32. The ingenious design of the first clamping assembly is not only reflected in its flexible first rotating jaws 44, but also in its two first semi-circular sleeves 47. These two first semi-circular sleeves 47, as key components that directly contact the tubing body 32, are carefully positioned at the other end of the corresponding first rotating jaws 44, together forming a stable clamping system for the tubing body 32. Specifically, each first semi-circular sleeve 47 is provided with a first arc-shaped groove 471. These two first arc-shaped grooves 471 are opposite to each other in the clamped state, forming a circular space that perfectly adapts to the outer wall surface of the tubing body 32. This design not only ensures a tight fit between the first semi-circular sleeve 47 and the oil pipe body 32, but also provides a uniform clamping force to the oil pipe body 32 through the shape and size of the first arc-shaped groove 471, avoiding local over-tightness or looseness. For example, the first semi-circular sleeve 47 can be made of, but is not limited to, rubber or silicone. During the clamping process, when the first cylinder 46 drives the two first rotating jaws 44 to approach each other, the two first semi-circular sleeves 47 also approach each other until their first arc-shaped grooves 471 completely cover the outer wall of the oil pipe body 32. At this time, the two first semi-circular sleeves 47 work together to apply a uniform and stable clamping force to the oil pipe body 32, ensuring the stability of the oil pipe during refueling. This design has multiple benefits. First, through the cooperative use of the two first semi-circular sleeves 47, the first clamping assembly can achieve all-around clamping of the oil pipe body 32, greatly improving the stability and reliability of the clamping. Even if the oil pipe is subjected to external forces or vibrations during refueling, it can maintain its positional stability, avoiding problems such as oil leakage or refueling interruption caused by oil pipe shaking or detachment. Secondly, due to the perfect fit between the first arc-shaped groove 471 and the outer wall of the oil pipe body 32, the first semi-circular sleeve 47 will not cause any damage or deformation to the oil pipe during clamping. This protects the service life of the oil pipe and ensures the smoothness and safety of fuel delivery. In addition, this design also improves the versatility and flexibility of the equipment. Oil pipe bodies 32 of different specifications and sizes can be perfectly adapted to the first clamping assembly simply by replacing the first semi-circular sleeve 47 of the corresponding size. This allows the power generation equipment to adapt to more types of oil pipes, expanding its application range.

[0053] Furthermore, the first reinforcement unit 4 also includes a lifting drive mechanism, which is mounted on the base plate 1. The output end of the lifting drive mechanism is connected to the lifting seat 42, and the lifting drive mechanism is used to drive the lifting seat 42 to move along the first direction. Specifically, the output end of the lifting drive mechanism is directly connected to the lifting seat 42, and through its powerful driving capability, it can precisely control the movement of the lifting seat 42 along the first direction. This design not only enables flexible adjustment of the height of the oil pipe body 32, but also ensures that the oil pipe body 32 can always maintain the optimal working position and angle under different working scenarios, thereby improving the operating efficiency and stability of the entire power generation equipment. Through the precise control of the lifting drive mechanism, the first reinforcement unit 4 can achieve dynamic adjustment of the position of the oil pipe body 32, ensuring the stability and safety of the oil pipe during the refueling process. Whether it is pre-stretching the oil pipe at the beginning of refueling or adjusting the height of the oil pipe according to actual needs during refueling, the lifting drive mechanism can provide stable and precise power support.

[0054] This embodiment offers several flexible options for selecting the lifting drive mechanism. For example, a cylinder can be used as the drive source, leveraging its rapid response and stable performance to achieve rapid and accurate adjustment of the lifting seat 42. The cylinder converts the energy of compressed air into mechanical energy through the movement of its internal piston, thereby driving the lifting seat 42 to move in the first direction. This solution has advantages such as simple structure and convenient maintenance, making it suitable for scenarios requiring high adjustment speed. Alternatively, an electric actuator is also a viable option. The electric actuator drives a screw to rotate via a motor, converting rotational motion into linear motion, thus driving the lifting seat 42. Compared to a cylinder, the electric actuator offers higher control precision and greater driving force, making it suitable for applications requiring high positional accuracy. Besides cylinders and electric actuators, gear and rack transmission modules or lead screw and slide modules are also excellent lifting drive solutions. Gear and rack transmission modules convert rotational motion into linear motion through the meshing of gears and racks, thereby driving the lifting seat 42 to move. Lead screw and slide modules, on the other hand, utilize the relative movement of the lead screw and nut to achieve precise movement of the lifting seat 42. These solutions each have their own advantages and disadvantages, and users can choose flexibly according to their actual needs without imposing too many restrictions here.

[0055] Furthermore, such as Figures 3 to 5As shown, the pipeline positioning module also includes a second reinforcement unit 5. The second reinforcement unit 5 includes a fixing plate 51 and a second clamping assembly. The fixing plate 51 is located on the top of the oil tank 22 and near the oil inlet. The second clamping assembly is located on the fixing plate 51 and is used to clamp or release the oil pipe body 32. As a key part of the power generation equipment to ensure the stable operation of the oil pipe system, the pipeline positioning module, especially the specially designed second reinforcement unit 5, plays a crucial role. The second reinforcement unit 5 not only further strengthens the fixing effect of the oil pipe body 32, but also improves the safety and reliability of the entire pipeline system. Specifically, the second reinforcement unit 5 is mainly composed of two core parts: the fixing plate 51 and the second clamping assembly. The fixing plate 51, as the basic support of the entire reinforcement unit, is precisely set on the top of the oil tank 22 and is particularly close to the critical position of the oil inlet. This layout design takes into account the stress situation of the oil pipe body 32 at the oil inlet and facilitates subsequent maintenance and repair of the oil pipe. The fixing plate 51 is firmly connected to the top of the oil tank 22 through a high-strength connection, ensuring its stability under various operating conditions and providing a solid support platform for the second clamping assembly. The second clamping assembly is a key component of the second reinforcement unit 5 that directly acts on the oil pipe body 32. It is cleverly positioned on the fixing plate 51, and through a precise mechanical structure and flexible drive mechanism, it achieves the clamping and releasing functions of the oil pipe body 32. When the oil pipe needs to be fixed, the second clamping assembly can quickly and accurately clamp the oil pipe body 32, ensuring its stable position; when the oil pipe position needs to be adjusted or maintenance is required, the second clamping assembly can easily release, providing convenience for operators. Firstly, in terms of safety, the second reinforcement unit 5 provides double protection for the oil pipe body 32 through the synergistic action of the fixing plate 51 and the second clamping assembly. The fixing plate 51 ensures the vertical stability of the oil pipe body 32, preventing oil leakage accidents caused by oil pipe shaking or detachment. The second clamping assembly further enhances the horizontal stability of the oil pipe body 32 by clamping it, effectively resisting the impact of external shocks and vibrations on the oil pipe body 32. Secondly, in terms of reliability, the adjustable clamping force design of the second clamping assembly allows it to adapt to oil pipe bodies 32 of different specifications and materials, further improving the versatility and reliability of the entire pipeline system. Furthermore, it simplifies the installation and maintenance process, providing strong support for the efficient operation of the power generation equipment. When it is necessary to replace the oil pipe or perform other maintenance operations, operators only need to loosen the second clamping assembly to easily remove the oil pipe body 32 from the fixing plate 51, without the need for large-scale disassembly of the entire pipeline system.

[0056] Furthermore, the second clamping assembly includes a connecting plate 54 and two second rotating jaws 52. Both second rotating jaws 52 are rotatably mounted on a fixed plate 51. A pin 53 is fixedly mounted at one end of each second rotating jaw 52, ​​and the other end of each second rotating jaw 52 abuts against the oil pipe body 32. The connecting plate 54 is located between the two second rotating jaws 52 and can move along a third direction. Second sliding grooves 541 are provided at both ends of the connecting plate 54, and the pin 53 passes through the second sliding grooves 541. The connecting plate 54 is used to drive the two second rotating jaws 52 to clamp or release the oil pipe body 32. As a core component of the second reinforcement unit 5 in the pipeline positioning module, the second clamping assembly not only achieves efficient fixation of the oil pipe body 32 but also simplifies the operation process through mechanical linkage, improving the safety and reliability of the entire power generation equipment. Specifically, the second clamping assembly mainly consists of a connecting plate 54 and two second rotating jaws 52. Both second rotating jaws 52 are rotatably mounted on the fixed plate 51, a design that grants them flexible movement capabilities. Each second rotating jaw 52 has a pin 53 fixedly mounted at one end, while the other end directly abuts against the oil pipe body 32, forming a stable clamping point. This design ensures clamping stability while avoiding potential damage to the oil pipe caused by a direct rigid connection. The connecting plate 54, serving as the power transmission element in the second clamping assembly, is cleverly positioned between the two second rotating jaws 52 and possesses the ability to move in a third direction. Each end of the connecting plate 54 has a second sliding groove 541, which engages with the pin 53 on the second rotating jaws 52. When the connecting plate 54 moves in a third direction, the pin 53 slides within the second sliding groove 541, thereby causing the second rotating jaw 52 to rotate around its fixed point. By moving the connecting plate 54, the clamping or releasing actions of both second rotating jaws 52 can be controlled simultaneously, eliminating the need for individual operation of each jaw. This not only simplifies the operation process but also improves work efficiency. For example, when it is necessary to fix the oil pipe body 32, simply move the connecting plate 54, and the two second rotating jaws 52 will automatically rotate and clamp the oil pipe; when it is necessary to release the oil pipe, simply move the connecting plate 54 in the opposite direction. Since the second rotating jaws 52 can rotate around their fixed point, they can adapt to oil pipe bodies 32 of different diameters and shapes. Whether it is a round, square, or other irregularly shaped oil pipe, the second clamping assembly can achieve a stable clamping by adjusting the rotation angle of the second rotating jaws 52. In summary, the second clamping assembly, through the synergistic action of the connecting plate 54 and the two second rotating jaws 52, achieves efficient, stable, and convenient clamping and releasing operations on the oil pipe body 32. This design not only improves the safety and reliability of the power generation equipment but also simplifies the operation process, enhances adaptability and versatility, and provides a strong guarantee for the efficient operation of the entire equipment.

[0057] Furthermore, the second clamping assembly also includes a second cylinder 55, which is mounted on a fixed plate 51. The piston rod of the second cylinder 55 is connected to a connecting plate 54, and the second cylinder 55 drives the connecting plate 54 to move in a third direction. The second cylinder 55, as a driving element, is mounted on the fixed plate 51, which serves as the foundation support for the entire second reinforcement unit 5, providing a stable mounting platform for the second cylinder 55. This ensures high stability during operation and prevents displacement due to external vibration or impact, thus guaranteeing the accuracy of the second cylinder 55's driving action. The piston rod of the second cylinder 55 is directly connected to the connecting plate 54. This connection method is simple and efficient, allowing the power of the second cylinder 55 to be transmitted to the connecting plate 54 without loss. When the second cylinder 55 receives a driving signal, the piston rod begins to perform linear reciprocating motion. Since the piston rod is connected to the connecting plate 54, this motion is directly converted into the movement of the connecting plate 54 in a third direction. This mechanical transmission method boasts advantages such as rapid response and precise action, enabling the movement of the connecting plate 54 to be completed in a short time, significantly improving the working efficiency of the second clamping assembly. In traditional clamping methods, manual operation of the connecting plate 54 may be required to clamp or release, which is not only labor-intensive but also difficult to guarantee operational accuracy. However, with the drive of the second cylinder 55, the operator only needs to send corresponding commands through the control system, and the second cylinder 55 can automatically move the connecting plate 54, thereby driving the two second rotating jaws 52 to clamp or release the oil pipe body 32. This automated operation not only reduces the operator's burden but also improves the accuracy and consistency of operation, effectively avoiding problems such as uneven clamping force or operational errors caused by human factors. In terms of performance improvement, because the second cylinder 55 can generate significant thrust and pull, it can easily drive the connecting plate 54 to drive the second rotating jaws 52 to securely clamp the oil pipe body 32. Even when the oil pipe body 32 is subjected to significant external force, the second cylinder 55 can ensure stable clamping force, preventing the oil pipe body 32 from loosening or falling off. Furthermore, the stroke and speed of the second cylinder 55 can be precisely adjusted according to actual needs, enabling the second clamping assembly to adapt to oil pipe bodies 32 of different specifications and operating conditions, further expanding its application range. In summary, the application of the second cylinder 55 in the second clamping assembly, through its powerful driving capability, precise transmission performance, and reliable safety assurance, provides a more efficient, stable, and safe oil pipe clamping solution for the pipeline positioning module. It not only improves the overall performance and operating efficiency of the power generation equipment but also lays a solid foundation for the automation and intelligent development of the equipment.

[0058] Furthermore, the second clamping assembly also includes two second semi-circular sleeves 56, which are disposed at the other end of the corresponding second rotating jaws 52. The second arcuate groove 561 of one of the second semi-circular sleeves 56 is opposite to the second arcuate groove 561 of the other second semi-circular sleeve 56. The second rotating jaws 52, as key components for power transmission and action execution, can drive the second semi-circular sleeves 56 to clamp or release through their own rotational movement. The design of the second semi-circular sleeves 56 further refines the clamping operation, making it more closely conform to the shape of the tubing body 32, thereby improving clamping stability and sealing. The second arcuate groove 561 matches the outer surface shape of the tubing body 32. When the two second semi-circular sleeves 56 approach each other and finally close, their second arcuate grooves 561 can perfectly wrap around the tubing body 32, forming a uniform clamping force. This uniform clamping force not only effectively prevents the tubing body 32 from shaking or shifting during operation, but also avoids tubing deformation or damage caused by excessive local clamping force. Regarding the clamping effect, the relative arrangement of the two second semi-circular sleeves 56 makes the clamping operation more precise and reliable. Due to the presence of the second arc-shaped groove 561, the tubing body 32 can be accurately positioned between the two second semi-circular sleeves 56 during clamping, ensuring the accuracy of the clamping position. Simultaneously, the second semi-circular sleeves 56 can be made of rubber or silicone. The material of the second semi-circular sleeves 56 typically has a certain degree of elasticity and toughness, allowing for fine-tuning according to the actual shape of the tubing body 32 during clamping, thereby further improving the fit and sealing of the clamping. When clamping the tubing body 32, simply drive the second rotating jaw 52 to rotate, bringing the two second semi-circular sleeves 56 closer together and ultimately closing them. When releasing the tubing body 32, simply drive the second rotating jaw 52 in the opposite direction to separate the two sleeves. Since the diameter and shape of the tubing body 32 may vary depending on the specifications and models, the second arc-shaped groove 561 of the second semi-circular jacket 56 can be adjusted in size and shape to accommodate these differences. Therefore, the second clamping assembly can be widely used in various power generation equipment to meet the tubing clamping requirements under different operating conditions. In terms of safety and reliability, the design of the two second semi-circular jackets 56 also plays a crucial role. Because they are tightly integrated with the second rotating jaw 52, ​​forming a stable clamping structure, they effectively prevent the tubing body 32 from loosening or falling off due to external impacts or vibrations during operation. At the same time, the material of the second semi-circular jackets 56 ensures long-term stable operation in harsh working environments, providing strong protection for the safe operation of power generation equipment.In summary, the application of the two second semi-circular sleeves 56 in the second clamping assembly provides a more efficient, stable, and safe oil pipe clamping solution for the pipeline positioning module through their precise positioning, uniform clamping force, convenient operation, wide adaptability, and reliable safety. This design not only improves the overall performance and operating efficiency of the power generation equipment but also lays a solid foundation for the long-term stable operation of the equipment.

[0059] Furthermore, such as Figure 1 Combination Figure 3 As shown, the pipeline positioning module also includes a third reinforcement unit 6 located between the oil pump 33 and the oil tank 31. The third reinforcement unit 6 includes a support rod 61, the bottom of which is connected to the base plate 1, and the top of which abuts against the oil pipe body 32. The support rod 61 in the third reinforcement unit 6 serves as a core support component, its bottom tightly connected to the base plate 1, ensuring that the support rod 61 remains stable even under immense pressure and vibration. The base plate 1, as the basic support structure of the entire power generation equipment, possesses sufficient strength and stability to provide a reliable point of force for the support rod 61. Through this bottom connection method, the support rod 61 provides a solid support foundation for the oil pipe body 32. During the operation of the power generation equipment, the oil pipe body 32 is subjected to various forces, including pressure from the oil pump 33, oil impact, and equipment vibration. If these forces are not effectively dispersed and supported, they can easily lead to deformation, loosening, or even damage to the oil pipe body 32, thereby affecting the normal operation of the entire equipment. Optionally, multiple third reinforcement units 6 can be installed along the extension path of the oil pipe body 32. The top of the support rod 61 abuts against the oil pipe body 32, acting as a reliable "backbone" for the oil pipe body 32. It can withstand and distribute various forces on the oil pipe body 32, transferring them to the base plate 1, thereby effectively reducing the stress on the oil pipe body 32 and protecting it from damage. The support rod 61 is made of high-strength, corrosion-resistant materials, such as stainless steel or alloy steel. These materials not only have sufficient strength to withstand the pressure of the oil pipe body 32 but also have good corrosion resistance, allowing for long-term use in harsh working environments without damage. The bottom of the support rod 61 is typically connected to the base plate 1 using bolts or welding. These connection methods are simple to operate and provide a strong connection. During installation, simply place the support rod 61 accurately in the predetermined position and fix it with bolts or welding. Furthermore, the height and angle of the support rod 61 can be adjusted according to actual needs to adapt to oil pipe bodies 32 of different specifications and operating conditions. This flexibility allows the third reinforcement unit 6 to have a wide range of applications.

[0060] Furthermore, the third reinforcement unit 6 also includes a third semi-circular jacket 62, which is mounted on the support rod 61. The third arc-shaped groove 621 of the third semi-circular jacket 62 abuts against the oil pipe body 32. The third arc-shaped groove 621 perfectly matches the outer surface shape of the oil pipe body 32. This highly fitted design creates a uniform contact surface between the jacket and the oil pipe body 32. When the oil pipe body 32 is subjected to various forces such as pressure from the oil pump 33, oil impact, and equipment vibration, the third arc-shaped groove 621 can evenly distribute these forces to various parts of the jacket, preventing oil pipe deformation or damage caused by excessive local stress. At the same time, the uniform contact surface also reduces friction between the oil pipe body 32 and the jacket, reducing wear and extending the service life of the equipment. The third semi-circular jacket 62 can be made of rubber or silicone. These materials not only have sufficient strength to withstand the enormous pressure of the oil pipe body 32, but also possess good toughness, allowing for elastic deformation under impact to absorb and buffer some energy, protecting the oil pipe body 32 from damage. The third semi-circular jacket 62 significantly improves the stability and reliability of the pipeline positioning module. During the operation of the power generation equipment, the oil pipe body 32 is subject to various dynamic forces, making it prone to swaying and displacement. The third arc-shaped groove 621 of the third semi-circular jacket 62 tightly abuts against the oil pipe body 32, effectively limiting its range of motion and maintaining a stable operating state. This stable operating state not only reduces fatigue damage to the oil pipe body 32 caused by swaying, but also lowers the risk of oil leakage, ensuring the normal operation of the equipment. Simultaneously, the jacket's supporting function provides better protection for the oil pipe body 32 when subjected to external impacts, preventing equipment downtime due to damage to the oil pipe body 32 and improving the overall operating efficiency of the equipment.

[0061] The application of the third reinforcement unit in the pipeline positioning module provides a stable and reliable operating environment for the main body of the oil pipe 32 through the stable support and effective protection of the support rod. It not only improves the overall performance and operating efficiency of the power generation equipment, but also provides a strong guarantee for the long-term stable operation and safe production of the equipment.

[0062] Optionally, the third semi-circular sleeve 62 is detachably installed on the support rod 61, such as by bolt connection. This connection method is not only convenient to install, but also facilitates subsequent maintenance and replacement. When the third semi-circular sleeve 62 is worn or damaged, it can be removed for repair or replacement simply by unscrewing the bolts, without the need for large-scale disassembly and modification of the entire support structure, greatly reducing maintenance costs and time. Since the diameter and shape of the oil pipe body 32 may vary depending on the specifications and models, the third arc-shaped groove 621 of the third semi-circular sleeve 62 can be adjusted in size and shape to accommodate these differences. Therefore, the third semi-circular sleeve 62 can be widely used in various power generation equipment to meet the oil pipe support requirements under different operating conditions.

[0063] The application of the third semi-circular jacket 62 in the third reinforcement unit provides a reliable and efficient support environment for the oil pipe body through its advantages such as precise positioning, uniform force distribution, stable support, and convenient installation and maintenance. It not only improves the overall performance and operating efficiency of the power generation equipment but also provides strong support for the long-term stable operation and safe production of the equipment. As a key support structure located between the oil pump 33 and the oil tank 31 in the pipeline positioning module, the third reinforcement unit's carefully designed third semi-circular jacket 62 further strengthens the overall support effect, providing comprehensive protection for the stable operation of the oil pipe body 32 and playing an indispensable role in improving equipment performance and reliability. The third semi-circular jacket 62, as one of the core components of the third reinforcement unit, is cleverly positioned on the support rod 61. This design is not arbitrary but has been rigorously verified through mechanical analysis and engineering practice. The support rod 61, as the basic support structure of the entire reinforcement unit, undertakes the important task of transferring the various forces on the oil pipe body 32 to the base plate 1.

[0064] Note that the above description is merely a preferred embodiment of the present invention and the technical principles employed. Those skilled in the art will understand that the present invention is not limited to the specific embodiments described herein, and various obvious changes, readjustments, and substitutions can be made without departing from the scope of protection of the present invention. Therefore, although the present invention has been described in detail through the above embodiments, the present invention is not limited to the above embodiments. Many other equivalent embodiments may be included without departing from the concept of the present invention, and the scope of the present invention is determined by the scope of the appended claims.

Claims

1. A power generation equipment, characterized in that, include: Base plate (1); The fuel-fired power generation module (2) includes a generator (21) and a fuel tank (22) mounted on the base plate (1), wherein the generator (21) is connected to the fuel tank (22); The refueling module (3) includes an oil tank (31), an oil pipe body (32), and an oil pump (33). The oil tank (31) is mounted on the base plate (1). One end of the oil pipe body (32) is connected to the oil tank (31), and the other end of the oil pipe body (32) is connected to the oil tank (22). The oil pump (33) is mounted on the base plate (1) and connected to the middle section of the oil pipe body (32). The pipeline positioning module includes a first reinforcement unit (4) disposed between the oil pump (33) and the oil tank (22). The first reinforcement unit (4) includes a guide rail (41), a lifting seat (42) and a first clamping assembly. The guide rail (41) is disposed on the base plate (1). The lifting seat (42) is disposed on the guide rail (41) and can slide along a first direction. The first clamping assembly is disposed on the lifting seat (42) and is used to clamp the oil pipe body (32) and can be lifted along the first direction.

2. The power generation equipment according to claim 1, characterized in that, The lifting seat (42) has two fixing bars (43) on the side near the oil pipe body (32), the fixing bars (43) extending in a second direction, and the first clamping assembly includes: Two first rotating jaws (44) are rotatably mounted on the corresponding fixed bar (43). One end of the first rotating jaw (44) is provided with a first sliding groove (441), and the other end of the first rotating jaw (44) is used to abut against the oil pipe body (32). A first cylinder (46) with a drive shaft (45) is disposed on the lifting seat (42). The drive shaft (45) passes through the first slide groove (441) of the two first rotating jaws (44). The first cylinder (46) is used to drive the two first rotating jaws (44) to rotate and clamp or release the oil pipe body (32).

3. The power generation equipment according to claim 2, characterized in that, The first clamping assembly further includes: Two first semi-circular sleeves (47) are disposed at the other end of the corresponding first rotating jaw (44), and the first arc groove (471) of one of the first semi-circular sleeves (47) is disposed opposite to the first arc groove (471) of the other first semi-circular sleeve (47).

4. The power generation equipment according to claim 1, characterized in that, The first reinforcement unit (4) further includes a lifting drive mechanism, which is disposed on the base plate (1). The output end of the lifting drive mechanism is connected to the lifting seat (42) in a transmission manner. The lifting drive mechanism is used to drive the lifting seat (42) to move along the first direction.

5. The power generation equipment according to claim 1, characterized in that, The pipeline positioning module also includes a second reinforcement unit (5), which includes a fixing plate (51) and a second clamping assembly. The fixing plate (51) is located on the top of the oil tank (22) and near the oil inlet. The second clamping assembly is located on the fixing plate (51) and is used to clamp or release the oil pipe body (32).

6. The power generation equipment according to claim 5, characterized in that, The second clamping assembly includes: Two second rotating jaws (52) are rotatably mounted on the fixed plate (51). One end of the second rotating jaw (52) is fixedly mounted with a pin (53), and the other end of the second rotating jaw (52) is used to abut against the oil pipe body (32). A connecting plate (54) is located between two second rotating jaws (52) and can move along a third direction. The two ends of the connecting plate (54) are respectively provided with second sliding grooves (541). The pin (53) passes through the second sliding grooves (541). The connecting plate (54) is used to drive the two second rotating jaws (52) to clamp or loosen the oil pipe body (32).

7. The power generation equipment according to claim 6, characterized in that, The second clamping assembly further includes: A second cylinder (55) is mounted on the fixed plate (51). The piston rod of the second cylinder (55) is connected to the connecting plate (54). The second cylinder (55) is used to drive the connecting plate (54) to move along the third direction.

8. The power generation equipment according to claim 6, characterized in that, The second clamping assembly further includes: Two second semicircular sleeves (56) are disposed at the other end of the corresponding second rotating jaws (52), and the second arc groove (561) of one of the second semicircular sleeves (56) is disposed opposite to the second arc groove (561) of the other second semicircular sleeve (56).

9. The power generation equipment according to any one of claims 1-8, characterized in that, The pipeline positioning module also includes a third reinforcement unit (6) located between the oil pump (33) and the oil tank (31). The third reinforcement unit (6) includes a support rod (61), the bottom of which is connected to the base plate (1), and the top of which abuts against the oil pipe body (32).

10. The power generation equipment according to claim 9, characterized in that, The third reinforcement unit (6) also includes a third semi-circular sleeve (62), which is disposed on the support rod (61), and the third arc groove (621) of the third semi-circular sleeve (62) abuts against the oil pipe body (32).