초록 ▼

A panel performance testing system and method of use is provided for evaluating creep and duration of load (DOL) performance of products, particularly wood-based panels, subjected to bending stress. The panel performance testing system comprises a panel testing support frame assembly; a loading hea

A panel performance testing system and method of use is provided for evaluating creep and duration of load (DOL) performance of products, particularly wood-based panels, subjected to bending stress. The panel performance testing system comprises a panel testing support frame assembly; a loading head assembly for applying test load to a panel face; a load transfer assembly for transferring load force from a dead weight to the loading head assembly; a panel deflection sensor; and a mobile loading platform assembly for vertically positioning and supporting dead weight loads, controlling the rate of load transfer of the dead weight loads from the loading platform assembly to the loading head assembly, and an integrated data acquisition system that automatically records and processes the related testing data for the entire course of the testing.

대표청구항 ▼

What is claimed is: 1. A panel performance testing system, comprising: a panel testing support frame assembly comprising first and second retaining assemblies for releasably retaining opposite end portions of a test panel in fixed position; a loading head assembly operable to impart a load to a fir

What is claimed is: 1. A panel performance testing system, comprising: a panel testing support frame assembly comprising first and second retaining assemblies for releasably retaining opposite end portions of a test panel in fixed position; a loading head assembly operable to impart a load to a first major face of a test panel between the retained opposite end portions of the panel; a load transfer assembly operable to mechanically couple at least one dead weight to the loading head assembly for load transfer therebetween; a sensor for measuring magnitude of deflection of the panel from an applied load and generating a signal indicative of the magnitude of panel deflection; a mobile loading platform assembly comprising a reciprocally vertically-movable platform for supporting the at least one dead weight, a linear actuator assembly comprising a motor controller and a linear actuator having an output shaft mechanically coupled to the platform, wherein the linear actuator assembly is operable to vertically move the platform at a controlled rate effective to load the load transfer assembly at a uniform rate with a progressively increasing amount of weight of the dead weight until the dead weight is fully transferred to the load transfer assembly and unsupported by the platform, a load cell for developing and transmitting load-indicating signals corresponding to amount of weight of the dead weight supported by the platform; a computerized control system operable to control actuation of the linear actuator assembly effective to control starting/stopping movement of the output shaft of the linear actuator, and receive and store the panel deflection signals and platform load-indicating signals and corresponding measurement times during initial loading of the load transfer assembly with the dead weight and during constant load conditions maintained thereafter for a period of time. 2. A panel performance testing system of claim 1, wherein computerized control system includes at least one input device and a central processing unit, and said computerized control system is operable for storing and executing a programmable load/deflection measuring program for performing a creep test on a panel. 3. A panel performance testing system of claim 1, wherein the computerized control system is operatively coupled to i) the motor controller for controlling starting and stopping translation of the output shaft of the linear actuator, and ii) said load cell and deflection sensor for receiving, recording and processing data relating to the applied load and the corresponding panel deflection, respectively, as a function of time during an initial loading period and a subsequent creep cycle testing period, and said computerized control system being operable to process the recorded test data to compute a measure of the creep of the panel. 4. A panel performance testing system of claim 1, wherein the motor controller is operable to control the rate of weight loading to a constant value between 0.005 to 5 inch per minute until the weight is fully suspended from the cable and unsupported by the platform. 5. A panel performance testing system of claim 1, wherein the mobile loading platform assembly further comprises a lift truck frame supporting the platform, the linear actuator, the computerized control system, and wheels for controlled movement of the lift truck frame towards and away from the test panel support frame assembly. 6. A panel performance testing system of claim 1, wherein the load head assembly comprises two rectilinear contact rods for applying load to the first major face of a test panel along two parallel lines of contact made by the respective rods along their lengths with the first major face. 7. A panel performance testing system of claim 1, wherein the linear actuator comprises a roller screw and rolling elements operably connected to a rotary power transmission source and the output shaft. 8. A panel performance testing system of claim 1, wherein the linear actuator comprises multiple threaded helical rollers assembled in a planetary arrangement around a portion of the output shaft comprising a threaded shaft, wherein the linear actuator converts rotary motion into linear movement of the threaded shaft. 9. A panel performance testing system of claim 8, further comprising a constant power transmission to power the linear actuator and a position feedback assembly operable to generate signals corresponding to the position and velocity of the output shaft of the linear actuator. 10. A panel performance testing system of claim 1, wherein the load transfer assembly comprises a pulley and cable, in combination, wherein the cable is operable for connecting the loading head assembly and dead weight, and the pulley includes a freely rotatable surface over which the cable may translate in a guided manner. 11. The panel testing device of claim 1, wherein the panel deflection sensor comprises an end portion supporting a deflection sensor, wherein the end portion being movable between a non-testing position where the sensor is out of contact with the panel and a test position where the sensor is in contact with the panel when the deflection sensor is in the test position operable to measure a deflection of the panel. 12. The panel performance system of claim 1, further comprising a computer monitor coupled in communication with the computerized control system, and operable to display panel test results. 13. The panel performance system of claim 1, wherein the deflection sensor is operable to output a signal indicative of panel deflection that is received at the computerized control system via wireless communication. 14. A method for testing a panel of material, comprising: (A) providing a panel performance testing system comprising a panel testing support frame assembly comprising first and second retaining assemblies for releasably retaining opposite end portions of a test panel in fixed position; a loading head assembly operable to impart a load to a first major face of a test panel between the retained opposite end portions of the panel; a load transfer assembly operable to mechanically couple at least one dead weight to the loading head for load transfer therebetween; a sensor for measuring magnitude of deflection of the panel from an applied load and generating a signal indicative of the magnitude of panel deflection; a mobile loading platform assembly comprising a reciprocally vertically-movable platform for supporting the at least one dead weight, a linear actuator assembly comprising a motor controller and a linear actuator having an output shaft mechanically coupled to the platform, wherein the linear actuator assembly is operable to vertically move the platform at a controlled rate effective to load the load transfer assembly at a uniform rate with a progressively increasing amount of weight of the dead weight until the dead weight is fully transferred to the load transfer assembly and unsupported by the platform, a load cell for developing and transmitting load-indicating signals corresponding to amount of weight of the dead weight supported by the platform; a computerized control system operable to control actuation of the linear actuator assembly effective to control starting/stopping movement of the output shaft of the linear actuator, and receive and record the panel deflection signals and platform load-indicating signals and corresponding measurement times during initial loading of the load transfer assembly with the dead weight and during constant load conditions maintained thereafter for a period of time; (B) immobilizing opposite ends of a test panel in the panel testing support frame with the retaining assemblies; (C) powering the linear actuator assembly in response to a starting command of the computerized control system effective to lower the support platform effective to load the load transfer assembly at a uniform rate with a progressively increasing amount of weight of the dead weight until the dead weight is fully suspended from the cable and unsupported by the platform; (D) maintaining, after step (C), the test panel under constant load for a given time period; (E) acquiring, during steps (C) and (D), panel deflection signals and platform load-indicating signals and corresponding measurement times at the computerized control system; (F) processing, at said computerized control system, said load-indicating signals and said deflection-indicating signals for deriving test results comprising the applied load, the deflection of the panel and corresponding measurement times. 15. The method of claim 14, wherein said deriving further includes calculating creep rate of the test panel. 16. The method of claim 14, comprising saving the test results in a data file format in the computerized control system. 17. The method of claim 14, wherein the test results are displayed on a computer monitor operatively coupled with the computerized control system. 18. The method of claim 14, wherein the deflection sensor outputs a signal indicative of panel deflection that is received at the computerized control system via wireless communication. 19. The method of claim 14, comprising determining panel creep rate of the test panel with the panel performance testing system in accordance with ASTM D6815-02a. 20. The method of claim 14, further comprising initially loading a plurality of different test panels supported on different respective test frames at different respective test stations located in the same test room by shuttling the same mobile platform assembly to successive different test stations after completing initial loading and while being absent during the constant stress portion of a creep test cycle as performed on a test panel at a previous test station.