Material

UM Material Data Sheet

UM material data sheets typically contain a variety of physical and mechanical property data. This data helps engineers and designers choose the right materials for different projects. Here are some common performance metrics:

Material\Project	Tensile Strength (MPa)	Expansion Rate (%)	Flexural Strength (MPa)	Flexural modulus (MPa)	Compressive strength (MPa)
904/9045	55	9.0	89	2689	88
6T	59	3.2	90	2399	33
9T	62	3.0	84	2206	93
9TP	66	3.0	94	2240	95
9TG02	80	2.5	135	3908	116
9TG06	100	2.0	167	8274	132
T2 (Triton 2000)	69	3.0	87	2143	94
T3 (Triton 3000)	138	2.0	214	10342	150
T5A (Triton 5000A)	130	2.0	210	10812	112
T5B (Triton 5000B)	110	2.0	198	17927	130

Material\Project	Specific Gravity	Coefficient of Friction (Aluminum)	Coefficient of friction (steel)	Applicable temperature ( °C )	PV value (MPa m/s)
904/9045	1.40	0.11	0.10	-30 ~ +85	0.53
6T	1.28	0.09	0.08	-40 ~ +130	2.61
9T	1.30	0.10	0.08	-40 ~ +160	5.25
9TP	1.32	0.11	0.09	-40 ~ +220	6.66
9TG02	1.35	0.14	0.12	-40 ~ +160	5.74
9TG06	1.50	0.16	0.15	-40 ~ +160	6.37
T2 (Triton 2000)	1.32	0.11	0.09	-40 ~ +160	5.95
T3 (Triton 3000)	1.45	0.18	0.17	+260	7.71
T5A (Triton 5000A)	1.43	0.14	0.13	+280	8.76
T5B (Triton 5000B)	1.43	0.12	0.11	+290	9.11

The above data is for reference. The actual selection should be analyzed in detail according to the specific application needs. If you need more detailed information or performance data for a specific material, please contact us.

There are also more material combinations that can be adjusted according to the customer’s usage situation.

Material Proper Noun Description

Tensile Strength

Tensile strength refers to the maximum stress that a material can withstand under tensile force until it breaks. This performance index is an important parameter for evaluating the material’s ability to resist deformation and fracture under tensile loads.

Elongation

Elongation refers to the percentage of elongation and deformation of the gauge part of the specimen compared to the original gauge when the material is stretched to fracture. It can withstand large deformations without breaking in applications and is suitable for structural parts that require high deformation capacity.

Flexural Strength

Flexural strength refers to the maximum stress that a material can withstand when it breaks during a bending test.

Flexural Modulus of Elasticity

Flexural elasticity coefficient refers to a parameter that measures the rigidity and resistance to deformation of a material under bending load.

Compressive Strength

Compressive strength refers to the maximum stress that a material can withstand under compressive load.

Specific Gravity

Also known as density, it is a physical quantity that describes the relationship between the mass of a material and its volume.

Coefficient of Friction

Represents the ratio of the normal force of the friction between two contact surfaces. It reflects the degree of friction between materials.

PV Value

PV value refers to the combination of the maximum pressure and speed that a material can withstand under high temperature and pressure conditions. PV value is the product of pressure and velocity, and is usually used to describe the performance of a material at high temperatures and pressures.

What does material number mean?

UM always manages materials by number. For example, you may see 904B1, 9TY1, 9TK1, 9TGK1, and many more.

The first 2 to 3 words represent the material base, 904 in 904B1, 9T in 9TY1, these words can be compared to the material data sheet to help you choose the base of the material, but it will vary according to different versions (the last word of the number), so the material performance is for reference only.

The last second word, B in 904B1, K in 9TGK1, represents color, for example, B is black, Y is yellow, and K is khaki (earth yellow). Since everyone has a different perception of color, and for convenience, the color is for reference only.

The last word represents the version, the same base, but different elements are mixed, and various versions are derived.

Material characteristics diagram

UM provides a simplified diagram of material characteristics, which is different from the material data sheet, which is relatively simple and simple, the purpose is to simplify the performance values, and it is empirical and consequential, so that everyone can directly read the key points, quickly interpret, and can confirm the difference between materials, for example:

Material characteristics diagram

904B1

Temperature: 80°C
Abrasion resistance: 🌑
UV resistance: 🌑🌑

Speed : 🌑
Dimensional stability-moisture absorption: 🌑🌑🌑
Dimensional stability-temperature: 🌑

Load : 🌑🌑
Adaptability to Aluminum: 🌑🌑🌑
Adaptability to iron: 🌑🌑

🌑 The more, the better the performance, up to three.
If you have any other special material requirements, please fill in the "Contact Form" or welcome to contact us.

Temperature, which indicates the maximum operating temperature of the material.
Speed indicates the ability of the material to adapt to the operating speed. 🌑 The more, the better
Load, which indicates the ability of the material to fit the weight. 🌑 The more, the better the load-bearing
Wear resistance indicates the overall performance of the material in terms of wear and friction. 🌑 The more, the better the durability.
UV resistance, indicating the material's resistance to UV rays. 🌑 The more, the better the resistance.
Dimensional stability - moisture absorption means that the size change of the material when absorbing water and moisture, 🌑 the more the size change will be.
Dimensional stability - temperature means that the size of 🌑 the material is affected by the temperature rise or fall, the more the size change is smaller.
The adaptability to aluminum means that the more the material rubs against the aluminum alloy material, 🌑 the better the performance.
Adaptability to iron means the performance of the material when it rubs against the iron material, 🌑 and the more, the better the performance.