Quality Inspection for Low Temperature Wax for Chicago Manufacturers
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Quality Inspection for Low Temperature Wax for Chicago Manufacturers Detail:
Automatic Temperature Regulating Agent Series is a kind of thermal expansion materials, which depends on principles that the substance expands when it is heated and constricts when it is cooled and a liquid is incompressible. It can automatically regulate temperature. When the ambient temperature goes up to the special value, Automatic Temperature Regulating Agent goes up to the special temperature with the ambient temperature, its unit volume increases. When the ambient temperature falls down to special value, Automatic Temperature Regulating Agent also falls down to the special temperature with the ambient temperature, its unit volume reduces. The agent is loaded in the purpose-made thermostatic element. The variation of ambient temperature takes a pressure and the thermostatic element takes a change, and this change brings the movement of either the appurtenance of the thermodynamic component or itself, thereby carrying out the automatic opening & closing function. All sorts of temperature controllers and the electrical switches are developed depending on the physical feature of Automatic Temperature Regulating Agent. It has been widely used in the fields of refrigeration, auto-control system, automobile industry, petrochemical industry, sanitary ware, heating and ventilating, electric electron, building, space & aviation etc.
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Model Number |
Appearance (Normal Temperature) |
Quality Standard |
||||||
|
Range of Temperature Control |
Effective Distance Travel |
Water-Solubility Acid and Alkali |
Mechanical Impurity |
|||||
|
A30-1 |
Powder, Cream |
30/40 |
7 |
Non. |
Non. |
|||
|
A30-2 |
Powder, Cream |
30/40 |
10 |
Non. |
Non. |
|||
|
A30-3 |
Powder, Cream |
3045 |
10 |
Non. |
Non. |
|||
|
A30-4 |
Powder, Cream |
30/60 |
8 |
Non. |
Non. |
|||
|
A30-5 |
Powder, Cream |
30/65 |
4 |
Non. |
Non. |
|||
|
A30-6 |
Powder, Cream |
30/85 |
10 |
Non. |
Non. |
|||
|
A32 |
Powder, Cream |
32/60 |
4 |
Non. |
Non. |
|||
|
A33 |
Powder, Cream |
33/45 |
6 |
Non. |
Non. |
|||
|
A35 |
Powder, Cream |
35/45 |
5 |
Non. |
Non. |
|||
|
A35-1 |
Powder, Cream |
35/45 |
10 |
Non. |
Non. |
|||
|
A35-2 |
Powder, Cream |
35/50 |
8 |
Non. |
Non. |
|||
|
A36 |
Powder, Slice , Column |
36/62 |
5.5 |
Non. |
Non. |
|||
|
A37 |
Powder, Slice , Column |
37/47 |
9 |
Non. |
Non. |
|||
|
A38 |
Powder, Slice , Column |
38/50 |
7 |
Non. |
Non. |
|||
|
A40 |
Powder, Slice , Column |
40/50 |
7 |
Non. |
Non. |
|||
|
A40-1 |
Powder, Slice , Column |
40/50 |
10 |
Non. |
Non. |
|||
|
A40-2 |
Powder, Slice , Column |
40/64 |
4 |
Non. |
Non. |
|||
|
A40-3 |
Powder, Slice , Column |
40/80 |
8 |
Non. |
Non. |
|||
|
A42 |
Powder, Slice , Column |
42/68 |
5 |
Non. |
Non. |
|||
|
A43 |
Powder, Slice , Column |
43/48 |
6 |
Non. |
Non. |
|||
|
A43-1 |
Powder, Slice , Column |
43/55 |
7 |
Non. |
Non. |
|||
Product detail pictures:
Our commission is always to provide our customers and clientele with best quality and aggressive portable digital products for Quality Inspection for Low Temperature Wax for Chicago Manufacturers, The product will supply to all over the world, such as: Algeria , Mumbai , Congo , Our solutions are produced with the best raw materials. Every moment, we constantly improve the production programme. In order to ensure better quality and service, we now have been focusing on the production process. We have got high praise by partner. We are looking forward to establishing business relationship with you.
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Featured publication:
Large-area electro-optic ZnTe terahertz emitters.
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We present a detailed experimental and theoretical study of terahertz (THz) generation and beam propagation in an optoelectronic THz system consisting of a large-area (ZnTe) electro-optic emitter and a standard electro-optic detector, and provide a comparison to typical biased GaAs emitters. As predicted by theory, in the absence of saturation the generated THz pulse energy is inversely proportional to the area of the optical pump beam incident on the emitter, although the detected on-axis electric field amplitude of the subsequently focused THz beam is practically independent of this area. This latter result promotes the use of larger emitter crystals in amplifier-laser-based THz systems in order to minimize saturation effects. Moreover, the generation of an initially larger THz beam also provides improved spatial resolution at intermediate foci between emitter and detector.
