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Copper Brazed Plate Heat Exchanger In Refrigeration Systems For Heat Transfer Between Refrigerant And The Cooling Medium
Heat Exchanger in common use heating cryogenic fluid or cooling high temperature fluid during the producing in petroleum, chemical industry, light industry, pharmacy, energy etc. transmit liquid to steam through nebulization . Heat Exchanger is elementary component such as heater, cooler , condenser and also the part of tech equipment .
Development :
Heat Exchanger is the energy-efficient equipment which realize heat
transfer between materials in two types or above two types fluid
with different temperature , make heat transmit from higher
temperature to lower temperature of the fluid , and make fluid
temperature match stated index in order to reach the require of
tech condition , in meanwhile , also the mainly equipment for
improving energy utilization rate . It is widely use in heating and
ventilation, pressure vessel , water treating equipment, chemical,
petroleum, metallurgy, electric power, ship, supply heating, food,
refrigeration air conditioner , pharmacy, etc ....
Features :
Corrugated Plate Design: BPHEs consist of corrugated plates that create turbulence and enhance heat transfer efficiency. The corrugations also provide structural rigidity to the plates, ensuring durability.
Compact Size: BPHEs have a compact and space-saving design due to the stacked plate configuration. This allows for efficient use of space, making them ideal for installations with limited footprint requirements.
Copper Construction: BPHEs are primarily made of copper, which offers excellent thermal conductivity. Copper ensures efficient heat transfer between the fluids, resulting in high thermal efficiency.
Brazing Technology: The plates in a copper BPHE are brazed together using copper-based brazing material. This fusion bonding technique creates a strong and leak-free connection, ensuring reliable performance.
High Thermal Performance: The combination of the corrugated plate design and copper's excellent thermal conductivity results in high heat transfer rates and efficient thermal performance.
Versatile Fluid Compatibility: Copper BPHEs can handle a wide range of fluids, including water, refrigerants, oils, and various industrial fluids. This versatility makes them suitable for diverse applications.
Resistance to Corrosion: Copper exhibits good corrosion resistance, making copper BPHEs suitable for applications involving aggressive or corrosive fluids. This extends the life of the heat exchanger and reduces the risk of performance degradation.
High Pressure and Temperature Capability: Copper brazed plate heat exchangers can operate under high-pressure and high-temperature conditions, making them suitable for demanding industrial applications.
Easy Maintenance: BPHEs are relatively easy to maintain. The smooth plate surfaces are easy to clean, and the absence of gaskets eliminates the need for gasket replacements, reducing maintenance requirements.
Modular Design: BPHEs can be easily expanded or modified by adding or removing plates based on changing heat transfer requirements. This flexibility allows for scalability and adaptability to different applications.
Low Fouling Potential: The turbulent flow created by the corrugated plates helps minimize fouling, reducing the frequency and intensity of cleaning and maintenance.
Cost-Effective: Copper brazed plate heat exchangers offer cost-effective solutions through their compact design, high thermal efficiency, and long-term durability. They help reduce energy consumption and installation costs.
Copper brazed plate heat exchangers (BPHEs) are extensively used in refrigeration systems for efficient heat transfer between the refrigerant and the cooling medium. Here's how they are applied in refrigeration:
Condensers: In refrigeration systems, the condenser plays a vital role in releasing heat from the high-pressure, high-temperature refrigerant. Copper BPHEs are commonly employed as condensers to transfer heat from the refrigerant to the surrounding air or water. The refrigerant, in a gaseous state, releases heat as it condenses into a liquid phase within the BPHE.
Evaporators: Evaporators are responsible for absorbing heat from the cooling space or product and evaporating the refrigerant to facilitate cooling. Copper BPHEs are widely used as evaporators due to their high thermal conductivity and efficient heat transfer capabilities. The evaporator absorbs heat from the surroundings, causing the refrigerant to evaporate and cool the desired area.
Heat Pumps: Heat pumps are refrigeration systems that can provide both heating and cooling capabilities. Copper BPHEs are employed in heat pump systems to transfer heat between the refrigerant and the surrounding medium. In heating mode, the heat pump absorbs heat from the outdoor air, ground, or water source and transfers it to the desired indoor space using the BPHE. In cooling mode, the process is reversed, and the heat pump releases heat to the outside environment.
Refrigerant-to-Refrigerant Heat Exchangers: In some refrigeration applications, multiple refrigerants with different temperature ranges or properties may be used. Copper BPHEs can be employed as refrigerant-to-refrigerant heat exchangers to transfer heat between different refrigerant circuits. This can be useful for heat recovery or optimizing system performance.
Product List and Data :
| TYPE | B(mm | C(mm | D(mm) | E(mm) | Thickness (mm) | Weight(Kg) | Max Flow (m3/h) | Design Pressure (Mpa) |
| SB14 | 77 | 42 | 206 | 172 | 9+2.3N | 0.7+0.06N | 8 | 1/3/4.5 |
| SB16 | 78 | 42 | 208 | 172 | 9+2.24N | 0.6+0.049N | 8 | 1/3/4.5 |
| SB18 | 95 | 50 | 210 | 165 | 7+3.1N | 0.7+0.06N | 8 | 1 |
| SB20B | 78 | 42 | 318 | 282 | 9+2.3N | 1+0.08N | 8 | 3/4.5 |
| SB20C | 77 | 42 | 313 | 278 | 10+1.28N | 0.9+0.07N | 8 | 3/4.5 |
| SB26 | 111 | 50 | 310 | 250 | 10+2.32N | 1.3+0.12N | 18 | 3/4.5 |
| SB26F | 107 | 50 | 307 | 250 | 10+1.98N | 1.3+0.1N | 18 | 3/4.5 |
| SB28B | 120 | 72 | 290 | 243 | 10+2.36N | 1.5+0.133N | 18 | 3/4.5 |
| SB28C | 120 | 63 | 290 | 234 | 10+2.36N | 1.5+0.133N | 18 | 3/4.5 |
| SB30 | 126 | 70 | 307 | 250 | 10+2.35N | 2.2+0.16N | 18 | 3/4.5 |
| SB52A | 111 | 50 | 526 | 466 | 9+2.32N | 2.6+0.21N | 18 | 3/4.5 |
| SB52B | 111 | 50 | 526 | 466 | 9+2.32N | 2.6+0.19N | 18 | 3/4.5 |
| SB53 | 106 | 50 | 522 | 466 | 9+2.1N | 2.6+0.27N | 18 | 3/4.5 |
| SB62A | 120 | 63 | 528 | 470 | 10+2.35N | 2.379+0.194N | 18 | 3/4.5 |
| SB62B | 120 | 63 | 528 | 470 | 10+2.35N | 2.379+0.194N | 18 | 3/4.5 |
| SB65 | 125 | 65 | 540 | 480 | 11+2.28N | 2.5+0.228N | 18 | 3/4.5 |
| SB95A | 189 | 92 | 616 | 519 | 11+2.7N | 7.8+0.44N | 42 | 3/4.5 |
| SB95B | 189 | 92 | 616 | 519 | 11+2.7N | 7.8+0.44N | 42 | 3/4.5 |
| SB120A | 246 | 174 | 528 | 456 | 10+2.34N | 7.2+0.52N | 42 | 3/4.5 |
| SB120B | 246 | 174 | 528 | 456 | 10+2.34N | 7.2+0.52N | 42 | 3/4.5 |
| SB190 | 303 | 179 | 695 | 567 | 13+2.3N | 12+0.61N | 100 | 1.6/2.1/3 |
| SB200A | 320 | 188 | 742 | 603 | 14+2.7N | 13+0.67N | 100 | 1.5/2.1/3 |
| SB200B | 320 | 188 | 742 | 603 | 14+2.7N | 13+0.67N | 100 | 1.5/2.1/3 |
| SB200E | 320 | 207 | 742 | 624 | 14+2.7N | 13+0.67N | 100 | 1.5/2.1/3 |
| SB202 | 319 | 188 | 741 | 603 | 16+2.85N | 13+0.957N | 100 | 2.1/3 |
| SB300 | 370 | 118(95.5) | 995 | 861(816) | 17+2.675N | 20+1.26N | 200 | 1.6/2.1/3 |
| SB500 | 304 | 179 | 982 | 854 | 17+2.29N | 26.6+0.93N | 200 | 2.1/3 |
| SB01 | 390 | 204 | 1320 | 1132 | 22+2.75N | 30+1.8N | 300 | 3/4.5 |
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