A power supply equipment aging test device

By designing a power equipment aging test device, utilizing a sliding adjustment plate and multiple detection components, the inconvenience of power equipment aging testing in existing technologies is solved, enabling centralized detection and rapid analysis of battery aging conditions, and improving detection efficiency and reliability.

CN224456989UActive Publication Date: 2026-07-03SUZHOU SUZI RODE AUTOMATION CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUZHOU SUZI RODE AUTOMATION CO LTD
Filing Date
2025-07-03
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing power supply equipment aging test devices are not convenient for efficient aging tests, leading to component aging and performance degradation, and even causing failures.

Method used

A power supply equipment aging test device was designed, including a partition, a door panel, and an aging test structure. The device slides and adjusts on a connecting rod and a support base plate via a movable plate. It combines a positive terminal connection post, a negative terminal connection post, and a battery status detector to perform battery aging tests. Multiple testing components are installed to improve testing efficiency.

Benefits of technology

It enables centralized detection and rapid analysis of battery aging conditions, improving the detection efficiency and reliability of power supply equipment, protecting the detection components, and reducing the risk of failure.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a power supply equipment aging test device, including a partition, a door panel, and an aging test structure. The partition and door panel are fixedly connected, and the aging test structure is fixedly connected inside the partition and door panel. The aging test structure is used for battery aging detection. A battery status detector is connected to a matching connecting post through a positive terminal connection post and a negative terminal connection post to perform battery aging detection. The battery is supported by a movable plate, which slides on a connecting rod and a support base plate to change the position of the battery for convenient testing. This utility model is a power supply equipment aging test device that achieves the purpose of aging testing of power supply equipment through its structural design.
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Description

Technical Field

[0001] This utility model relates to the technical field of power supply equipment aging test equipment, specifically a power supply equipment aging test device. Background Technology

[0002] With the rapid development of power electronics technology, power supply equipment has become a core component in fields such as communications, aerospace, and new energy. Its reliability is directly related to the stable operation of the system. However, power supply equipment faces complex operating conditions such as high temperature, high humidity, and voltage fluctuations during long-term operation, leading to component aging, performance degradation, and even failure. Statistics show that approximately 60% of power supply equipment failures are due to aging failures. Therefore, building an efficient aging test device has become a key link in ensuring the quality of power supply equipment. The current structure is not convenient for conducting efficient aging tests. Utility Model Content

[0003] The purpose of this invention is to provide a power supply equipment aging test device to solve the problems mentioned in the background art.

[0004] To achieve the above objectives, the present invention provides the following technical solution: a power supply equipment aging test device, comprising a partition, a door panel and an aging test structure, wherein the partition and the door panel are fixedly connected, and the aging test structure is fixedly connected inside the partition and the door panel;

[0005] The aging test structure is used for battery aging detection. The battery status detector is connected to the positive terminal connection post, negative terminal connection post and matching connection post to perform battery aging detection. The battery is supported by a movable plate, which slides on the connecting rod and support base plate to change the position of the battery for easy testing.

[0006] Specifically, the aging test structure includes a backplate and a testing component. The testing component is installed on the backplate. The testing component includes a first separator, a positive electrode connection post, a negative electrode connection post, a battery status detector, and a second separator. The second separator is fixedly connected to the side end of the first separator. A battery status detector is provided between the first separator and the second separator. The battery status detector is provided with a positive electrode connection post and a negative electrode connection post.

[0007] Specifically, the detection component also includes a battery, a connecting post, a movable plate, a connecting rod, and a supporting base plate. The supporting base plate is fixedly connected to the side end of the first partition block, and a connecting rod is fixedly connected to the supporting base plate. The movable plate slides on the connecting rod and the supporting base plate. The upper end of the movable plate is provided with a battery, and the battery is provided with a connecting post.

[0008] Specifically, the battery is provided with two mating connection posts, which are respectively connected to the positive electrode connection post and the negative electrode connection post for battery aging detection.

[0009] Specifically, the battery status detector is configured as DLX-RTBT.

[0010] Specifically, the connection between the mating connection post and the positive and negative connection posts is made by means of a wire connection.

[0011] Compared with the prior art, the beneficial effects of this utility model are:

[0012] 1. By installing partitions and door panels, the aging test structure is supported, and the aging test structure is used for testing. The movable plate slides and adjusts on the connecting rod and support base plate. The battery status detector is connected to the two mating connecting posts on the battery through the positive terminal connecting post, the negative terminal connecting post, and the wire, thereby performing the connection processing work and analyzing the aging condition of the battery.

[0013] Second, by installing multiple testing components within the aging test structure, multiple batteries can be analyzed and processed to analyze their usage, thereby improving the centralized testing of batteries. The separator, door panel, and back panel are fixed to protect the testing components and accelerate the analysis and summarization of battery data. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the main structure of the present utility model;

[0015] Figure 2 This is an exploded view of the main body of this utility model;

[0016] Figure 3 This is a perspective view of the aging test structure of this utility model;

[0017] Figure 4 This is a perspective view of the detection component of this utility model;

[0018] Figure 5 This is an exploded view of the detection component of this utility model.

[0019] In the diagram: 1-Separator; 2-Door panel; 3-Aging test structure; 4-Back panel; 5-Detection component; 6-First separator; 7-Positive electrode connection post; 8-Negative electrode connection post; 9-Battery status detector; 10-Second separator; 11-Battery; 12-Matching connection post; 13-Modible plate; 14-Connecting rod; 15-Supporting base plate. Detailed Implementation

[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0021] Please see Figure 1-5 The present invention provides a technical solution: a power supply equipment aging test device, including a partition 1, a door panel 2 and an aging test structure 3, wherein the partition 1 and the door panel 2 are fixedly connected, and the aging test structure 3 is fixedly connected inside the partition 1 and the door panel 2.

[0022] The aging test structure 3 is used for aging detection of battery 11. Battery status detector 9 is connected to the positive terminal connection post 7, negative terminal connection post 8 and the matching connection post 12 to perform aging detection of battery 11. Battery 11 is supported by movable plate 13, which slides on connecting rod 14 and support base plate 15 to change the position of battery 11 for easy detection. By installing multiple detection components 5 in the aging test structure 3, multiple batteries 11 are analyzed and processed to analyze the usage of battery 11 and improve the centralized detection of battery 11. The separator 1, door panel 2 and back plate 4 are fixed to protect the detection components 5 and improve the speed of analysis and summary of battery 11.

[0023] The aging test structure 3 includes a back plate 4 and a detection component 5. The detection component 5 is installed on the back plate 4. The detection component 5 includes a first separator 6, a positive electrode connection post 7, a negative electrode connection post 8, a battery status detector 9, and a second separator 10. The second separator 10 is fixedly connected to the side end of the first separator 6. The battery status detector 9 is provided between the first separator 6 and the second separator 10. The battery status detector 9 is provided with a positive electrode connection post 7 and a negative electrode connection post 8.

[0024] The testing component 5 also includes a battery 11, a mating connecting post 12, a movable plate 13, a connecting rod 14, and a supporting base plate 15. The supporting base plate 15 is fixedly connected to the side end of the first partition block 6, and the connecting rod 14 is fixedly connected to the supporting base plate 15. The movable plate 13 slides on the connecting rod 14 and the supporting base plate 15. The battery 11 is provided at the upper end of the movable plate 13, and the mating connecting post 12 is provided on the battery 11. By installing the partition plate 1 and the door plate 2, the aging test structure 3 is supported, and the aging test structure 3 is used for testing. The movable plate 13 slides and adjusts on the connecting rod 14 and the supporting base plate 15. The battery status detector 9 is connected to the two mating connecting posts 12 on the battery 11 through the positive terminal connecting post 7, the negative terminal connecting post 8, and the wire, so as to perform connection processing and analyze the aging condition of the battery 11.

[0025] The battery 11 is provided with two mating connection posts 12, which are connected to the positive terminal connection post 7 and the negative terminal connection post 8 respectively, for aging testing of the battery 11.

[0026] The battery status tester 9 uses the DLX-RTBT8320 model.

[0027] The connection between the connecting post 12 and the positive connecting post 7 and the negative connecting post 8 is made by using a wire connection.

[0028] Working principle: When needed, the user first pulls out the movable plate 13, allowing it to slide and adjust on the connecting rod 14 and the supporting base plate 15. The battery 11 is then placed on the movable plate 13. The battery 11 is then connected to the battery 11 via the positive terminal 7, negative terminal 8, and wires on the battery status detector 9, thus connecting the battery 11 to the battery status detector 9. The movable plate 13 is then reset on the connecting rod 14 and the supporting base plate 15 to perform aging analysis of the battery 11. The first partition block 6 and the second partition block 10 provide protective support for the battery status detector 9, improving its load-bearing capacity. The aging test structure 3 is implemented by installing the partition 1 and the door panel 2. The battery is supported by the aging test structure 3, and the movable plate 13 slides and adjusts on the connecting rod 14 and the supporting base plate 15. The battery status detector 9 is connected to the two mating connecting posts 12 on the battery 11 through the positive terminal connecting post 7, the negative terminal connecting post 8 and the wire, so as to perform the connection processing work and analyze the aging condition of the battery 11. By installing multiple detection components 5 in the aging test structure 3, multiple batteries 11 are analyzed and processed, so as to analyze the usage of the battery 11 and improve the centralized detection of the battery 11. The separator 1, the door panel 2 and the back plate 4 are fixed to protect the detection components 5 and improve the speed of the analysis and summary of the battery 11 to complete the work.

[0029] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A power supply device burn-in test apparatus characterized by comprising: It includes a partition (1), a door panel (2) and an aging test structure (3), wherein the partition (1) and the door panel (2) are fixedly connected, and the aging test structure (3) is fixedly connected inside the partition (1) and the door panel (2); The aging test structure (3) is used for aging detection of the battery (11). The battery status detector (9) is connected to the matching connection post (12) through the positive terminal connection post (7) and the negative terminal connection post (8) to perform aging detection of the battery (11). The battery (11) is supported by the movable plate (13). The movable plate (13) slides on the connecting rod (14) and the support base plate (15) to change the position of the battery (11) for easy detection.

2. The power supply device burn-in test apparatus of claim 1, wherein: The aging test structure (3) includes a back plate (4) and a detection component (5). The detection component (5) is installed on the back plate (4). The detection component (5) includes a first separator (6), a positive electrode connection post (7), a negative electrode connection post (8), a battery status detector (9), and a second separator (10). The second separator (10) is fixedly connected to the side end of the first separator (6). The battery status detector (9) is provided between the first separator (6) and the second separator (10). The battery status detector (9) is provided with a positive electrode connection post (7) and a negative electrode connection post (8).

3. The power supply device burn-in test apparatus of claim 2, wherein: The detection component (5) also includes a battery (11), a connecting post (12), a movable plate (13), a connecting rod (14), and a supporting base plate (15). The supporting base plate (15) is fixedly connected to the side end of the first partition block (6). The connecting rod (14) is fixedly connected to the supporting base plate (15). The movable plate (13) slides on the connecting rod (14) and the supporting base plate (15). The upper end of the movable plate (13) is provided with a battery (11), and the battery (11) is provided with a connecting post (12).

4. The power supply device burn-in test apparatus of claim 3, wherein: The battery (11) is provided with two mating connection posts (12), which are connected to the positive electrode connection post (7) and the negative electrode connection post (8) respectively, for aging detection of the battery (11).

5. The power supply device burn-in test apparatus of claim 4, wherein: The battery status detector (9) is a DLX-RTBT8320 model.

6. The power device burn-in test apparatus of claim 5, wherein: The connection between the mating connecting post (12) and the positive connecting post (7) and the negative connecting post (8) is made by wire connection.