Mathematical description of matter exchange between water components and adsorbing surface of filter medium of water purification units

Desain penyejuk udara juga dapat diterapkan di bidang kesehatan, dengan standar Cleanroom dapat diperoleh suhu, kelembaban, kenyamanan dan kebersihan yang dibutuhkan untuk ruang steril (ruang bedah). Perancangan pendingin udara dalam hal ini dilakukan dengan menentukan beban pendinginan yang diperlukan untuk ruang steril (ruang bedah), kemudian menentukan ukuran ducting, jalur ducting, dan jumlah penggunaan ducting. Desain ini menggabungkan unit split saluran yang dimodifikasi, kipas booster, filter pra, filter medium, dan filter HEPA dengan menggunakan saluran aluminium preinsulated sebagai saluran udara. Desain dilakukan dengan menggunakan perangkat lunak AutoCAD 2012, Design Tools Duct Sizer, dan Microsoft Excel. Dari hasil perhitungan dan desain didapatkan kebutuhan kapasitas 3 ruang bedah yaitu ducted ducted 100.000 BTUH sebanyak 3 unit, booster fan 3.3 - 4 Di WG sebanyak 3 unit, pre filter 24 "x 24" x 2 "6 set, filter menengah 610 x 610 x 290 mm 6 set, dan filter HEPA 1220 x 610 x 70 mm 12. Untuk ruang steril, tekanan statis yang dihasilkan oleh unit pendingin harus lebih besar daripada tekanan statis yang dihasilkan dari unit yang ada. di ruang semi steril. Dengan kata lain, ruang steril harus memiliki tekanan positif terhadap ruang semi steril. Hal ini dimaksudkan agar udara di ruang semi steril tidak masuk ke ruang steril ketika pintu antar ruangan dibuka. Desain dan perhitungan ruang bedah, suhu nyata yang diperoleh adalah 23 ° C ± 2 ° C dan kelembaban relatif yang diperoleh adalah 60% ± 2%. Air conditioning design can also be applied in the health field, with cleanroom standard can be obtained temperature, humidity, comfort and hygiene needed for sterile room (surgical room). The design of air conditioning in this case is done by determining the cooling load required for the sterile room (surgical room), then determining the ducting size, ducting path, and the amount of ducting usage. This design combines modified ducted split unit, booster fan, pre filter, medium filter, and HEPA filter by using preinsulated aluminum duct as an air passage. The design is done by using AutoCAD 2012 software, Design Tools Duct Sizer, and Microsoft Excel. From the calculation and design result obtained the capacity requirement of 3 surgical room that is split ducted 100.000 BTUH as many as 3 units, booster fan 3.3 - 4 In WG as many as 3 units, pre filter 24"x 24" x 2" 6 sets, medium filter 610 x 610 x 290 mm 6 sets, and HEPA filter 1220 x 610 x 70 mm 12 sets. For the sterile room, the static pressure generated by the cooling unit shall be larger than the static pressure generated from the unit present in the semi sterile room. In other words, the sterile room must have positive pressure to the semi sterile room. It is intended that the air in the semi sterile room does not enter into the sterile room when the door between room opened. In this surgical room design and calculation, real temperature obtained is 23 °C ± 2 °C and the relative moisture obtained is 60% ± 2%.

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Study on the Modes of Operation of a Multi-Machine Installations with Mechanical Reduction

Alternative Energy and Ecology (ISJAEE) ◽

10.15518/isjaee.2019.10-12.012-022 ◽

2019 ◽

pp. 12-22

Author(s):

A. M. Oleynikov ◽

L. N. Kanov

Keyword(s):

Mathematical Description ◽

Reactive Power ◽

Maximum Efficiency ◽

Wind Flow ◽

System Of Equations ◽

Mechanical Equilibrium ◽

Synchronous Generators ◽

Electromagnetic Excitation ◽

Number Of Generators ◽

Wide Range

The paper gives the description of the original wind electrical installation with mechanical reduction in which the output of vertical axis wind turbine with rather low rotation speed over multiplicator is distributed to a certain number of generators. The number of acting generators is determined by the output of actual operating wind stream at each moment. According to this constructive scheme, it is possible to provide effective and with maximum efficiency installation work in a wide range of wind speeds and under any schedule issued to the consumer of electricity. As there are no any experience in using such complexes, mathematical description of its main elements is given, namely windwheels, generators with electromagnetic excitation of magnetic electrical type, then their interaction with windwheel, and also the results of mathematical modeling of work system regimes under using the offered system of equations. The basis for the mathematical description of the main elements of the installation – synchronous generators – are the system of equations of electrical and mechanical equilibrium in relative units in rotating coordinates without considering saturation of the magnetic circuit. The equation of mechanical equilibrium systems includes torque and brake windwheel electromagnetic moments of generators with taking into account the reduction coefficients and friction. In addition, we specify the alternator rotor dynamics resulting from continuous torque of windwheel fluctuations under the influence of unsteady wind flow and wind speed serving as the original variable is modeled by a set of sinusoids. Model simplification is achieved by equivalization of similar generators and by disregarding these transitions with a small time constant. Calculation the installation with synchronous generators of two types of small and medium capacity taking into account the operational factors allowed us to demonstrate the logic of interactions in the main elements of the reported complex in the process of converting wind flow into the generated active and reactive power. We have shown the possibility of stable system work under changeable wind stream condition by regulating of the plant blade angle and with simultaneous varying of generator number of different types. All these are in great interest for project organizations and power producers.

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Classification and Methods for Mathematical Description of Bank Risks

Journal of Automation and Information Sciences ◽

10.1615/jautomatinfscien.v41.i2.30 ◽

2009 ◽

Vol 41 (2) ◽

pp. 38-52

Author(s):

Petr I. Bidyuk ◽

Andrey .B. Basarab ◽

Aidyn Sardar ogly Gasanov

Keyword(s):

Mathematical Description ◽

Bank Risks

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Study of Low Cost Adsorbent for Drinking Water Purification

Journal of Environmental Science Computer Science and Engineering & Technology ◽

10.24214/jecet.a.6.3.10116 ◽

2017 ◽

Vol 6 (3) ◽

Keyword(s):

Drinking Water ◽

Water Purification ◽

Low Cost ◽

Drinking Water Purification

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Fouling Is the Beginning: Upcycling Biopolymer-Fouled Substrates for Fabricating High-Permeance Thin-Film Composite Polyamide Membranes

10.26434/chemrxiv.12121896 ◽

2020 ◽

Author(s):

Ruobin Dai ◽

Hongyi Han ◽

Tianlin Wang ◽

Jiayi Li ◽

Chuyang Y. Tang ◽

...

Keyword(s):

Thin Film ◽

High Pressure ◽

End Of Life ◽

Water Purification ◽

Low Pressure ◽

Polymeric Membranes ◽

Membrane Recycling ◽

Film Composite ◽

Thin Film Composite ◽

First Time

Commercial polymeric membranes are generally recognized to have low sustainability as membranes need to be replaced and abandoned after reaching the end of their life. At present, only techniques for downcycling end-of-life high-pressure membranes are available. For the first time, this study paves the way for upcycling fouled/end-of-life low-pressure membranes to fabricate new high-pressure membranes for water purification, forming a closed eco-loop of membrane recycling with significantly improved sustainability.

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DISINFEKSI UNTUK PROSES PENGOLAHAN AIR MINUM

Jurnal Air Indonesia ◽

10.29122/jai.v3i1.2314 ◽

2018 ◽

Vol 3 (1) ◽

Author(s):

Nusa Idaman Said

Keyword(s):

Drinking Water ◽

Water Purification ◽

Distribution System ◽

Residual Effect ◽

Drinking Water Treatment ◽

Disinfection Byproducts ◽

Water Disinfection ◽

Pathogenic Microorganisms ◽

Microbiological Contamination ◽

Disinfection Process

Water disinfection means the removal, deactivation or killing of pathogenic microorganisms. Microorganisms are destroyed or deactivated, resulting in termination of growth and reproduction. When microorganisms are not removed from drinking water, drinking water usage will cause people to fall ill. Chemical inactivation of microbiological contamination in natural or untreated water is usually one of the final steps to reduce pathogenic microorganisms in drinking water. Combinations of water purification steps (oxidation, coagulation, settling, disinfection, and filtration) cause (drinking) water to be safe after production. As an extra measure many countries apply a second disinfection step at the end of the water purification process, in order to protect the water from microbiological contamination in the water distribution system. Usually one uses a different kind of disinfectant from the one earlier in the process, during this disinfection process. The secondary disinfection makes sure that bacteria will not multiply in the water during distribution. This paper describes several technique of disinfection process for drinking water treatment. Disinfection can be attained by means of physical or chemical disinfectants. The agents also remove organic contaminants from water, which serve as nutrients or shelters for microorganisms. Disinfectants should not only kill microorganisms. Disinfectants must also have a residual effect, which means that they remain active in the water after disinfection. For chemical disinfection of water the following disinfectants can be used such as Chlorine (Cl2), Hypo chlorite (OCl-), Chloramines, Chlorine dioxide (ClO2), Ozone (O3), Hydrogen peroxide etch. For physical disinfection of water the following disinfectants can be used is Ultraviolet light (UV). Every technique has its specific advantages and and disadvantages its own application area sucs as environmentally friendly, disinfection byproducts, effectivity, investment, operational costs etc. Kata Kunci : Disinfeksi, bakteria, virus, air minum, khlor, hip khlorit, khloramine, khlor dioksida, ozon, UV.

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ELECTROKINETIC PROPERTIES AND SANITARY-HYGIENIC SAFETY OF WATER BIODISPERSIONS DURING ELECTROPROCESSING

Oil and Gas Studies ◽

10.31660/0445-0108-2017-6-123-126 ◽

2017 ◽

pp. 123-126

Author(s):

S. V. Vorobjeva ◽

O. V. Smirnov ◽

V. O. Smirnova ◽

T. V. Semenova

Keyword(s):

Water Purification ◽

Electrokinetic Properties

A correlation between the electrokinetic properties of biodispersion and the possibility of increasing the efficiency of water purification in electroprocessing is shown.

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