What are the structural safety tests for cardboard cat houses

When conducting structural safety tests, it is first necessary to establish a set of scientific evaluation standards to ensure the accuracy and reliability of the test results. In view of the design characteristics of Cardboard Cat House, the test should cover multiple aspects such as static load, dynamic load, connection structure strength, stability and fatigue durability.

As a basic link, static load test can effectively evaluate the load-bearing limit of the cat house under static conditions. During the test, simulated loads of different sizes should be selected to ensure the comprehensiveness and representativeness of the test. By gradually applying pressure to the structure and observing its performance under different load conditions, it can provide an important basis for design improvement.

Dynamic load test focuses on simulating the actual activity state of cats, especially jumping and fast in and out. Through the drop simulation test, the impact resistance of the cat house when it is subjected to instantaneous impact can be effectively tested. The test results of this link will directly affect the safety of the product in daily use, ensuring that cats will not be harmed by structural problems when they are active.

The strength test of the connection structure cannot be ignored. Since the design of Cardboard Cat House is mainly based on slot splicing and glue fixation, the stability of the connection part is directly related to the safety of the overall structure. By applying pull-out and torque tests to the connection points, its durability after long-term use can be evaluated to ensure that the product remains stable under multiple disassembly and repetitive loading.

The stability test is to verify the cat house's anti-overturning ability under different stress conditions. In particular, for products with a small bottom area or complex design, strict overturning tests must be carried out to prevent the risk of tipping due to unstable center of gravity. By adjusting the bottom center of gravity or thickening the bottom plate design, the stability of the product can be effectively improved to ensure the safety of cats during use.

Finally, fatigue durability testing is a key verification of the long-term safety of the product. By simulating repeated use actions and applying a large amount of repeated loading to materials and connectors, potential structural risks can be revealed. This test can provide an important reference for product material selection and design optimization, ensuring that there will be no safety hazards caused by material fatigue during long-term use.