Zute gị na Automechanika Shanghai ngosi!

Zute gị na Automechanika Shanghai ngosi!

Automechanika Shanghai 2017
Booth NO .: 3F68 na Ụlọ Nzukọ 3
Ụbọchị: 29th Nov - 2nd Dec 2017
Add: National Exhibition and Convention Center (Shanghai), China.
Weebụsaịtị: http://


Oge ijiji, Automechanika Shanghai 2017 ga-emepe ọnụ ụzọ ya naanị n'ime izu abụọ! Automechanika Shanghai bụ ọpụrụiche ahia kachasị mma nke Asia nyere maka akụkụ akụrụngwa, ngwa, akụrụngwa na ọrụ. N'afọ a, a na-atụ anya ka a nabatara ihe ngosi 6,000 na obodo na mpaghara iri anọ na anọ, ọ ga-ewetakwa ụfọdụ ọganihu kachasị ọhụrụ site n'aka ụlọọrụ nke ụwa na ụlọ. E sitere na 29 November - 2 December 2017 na Ụlọ Nzukọ Mba na Ụlọ Mgbakọ na Shanghai, China, ihe ngosi ahụ ga-emeghe ọnụ ụzọ ya gaa ihe dịka mmadụ 130,000 na ndị isi na-arụ ọrụ site na ụlọ ọrụ na-adọkpụ. Ihe ngosi ahụ emeela ka aha ya dị ka ọrụ 'ga-aga' maka ọrụ mgbasa ozi, ahịa, ịzụ ahịa na agụmakwụkwọ, na-eje ozi n'ozuzu nke ụlọ ọrụ na-emepụta ngwá ọrụ site na Parts & Components, Ndozi & Ndozi, Ngwa & Customizing na Electronics & Systems.

China-Lutong nwere obi ụtọ ịkwusa na anyị na-aga Shanghai na November iji soro na Automechanika Shanghai 2017. Nọmba ụlọ ntu anyị bụ 3F68 na Ụlọ nke 3. China-Lutong bụ otu n'ime ndị na-enye ihe nkedo ụgbọala na ihe ndị yiri ya. na China, nke nwere ihe karịrị afọ iri atọ na ahụmahụ, China Lutong bụ onye ndú nke ụlọ ọrụ ụgbọala. A nabatara gị nke ọma iji gaa n'ụlọ ntu anyị 3F68 na Ụlọ 3.

China Lutong Parts Plant is a professional OEM & Aftermarket parts supplier, which specialized in diesel engine parts. Our main products include plunger barrel,Control Valve, Injectors,common rail valve, Head rotor (VE Pump Parts), Plunger, Delivery Valve, Cam Disk, Repair Kits, Feed Pump and more.

Automechanika Shanghai, nke abụọ kachasị mma ahia ahia nke Autentchanika maka akụkụ akụrụngwa, ngwa, akụrụngwa na ọrụ. Ihe ngosi gụnyere akụkụ dị iche iche nke ihe ndị ọzọ na-ahụ maka diesel gụnyere Rotor Head (VE pump parts), Nozzle, Diesel Plunger / Element, Valve Valve, Valve Valve, Ngwọrọgwụ Rail Common, Disk Cam, Ndozi Nlekọta, Nri Nri, na VE Pump etc. a na-emepụta ngwaahịa na nrube isi nke mba ụwa site na iji akụrụngwa kachasị akụrụngwa na nkà na ụzụ na-egbusi oge. N'ihi njedebe dị mma ha, ịrụ ọrụ siri ike na ndụ ogologo oge, usoro ahịa anyị na-enwe mmasị dị ukwuu site na ndị ahịa anyị bara uru. Ọrụ anyị, ọrụ ndị na-anabata ndị ahịa na itinye aka na nkwalite n'ihu, na-akwado nkwado ego siri ike, ga-eme ka aha China Lutong bụrụ ihe a pụrụ ịdabere na ya, nke dị elu, ngwaahịa ndị ọhụrụ ga-aga n'ihu.

Anyị na-atụ anya ịhụ gị na Automechanika Shanghai 2017!

Inclined plate clarifier

Feiyiya Inclined Plate Clarifiers Use Gravity & Innovative Engineering

A gravity clarifier is the most economical method of removing solids from liquids, using natural gravity as the source of energy and it is free. A clarifier simply provides a non-turbulent zone where heavier than liquid solids, suspended by turbulence, are given sufficient time to settle to a quiescent surface. The HEI inclined plate clarifiers are compact units with multiple layers of settling area utilizing less than 25% of the floor space required by conventional clarifiers.

Principle of Clarifiers

A particle carried forward by the velocity of the liquid flow must settle at a rate that allows it to reach the bottom before passing through the clarifer. Thus, particles beginning at a point [a" must traverse some route lying between ab and ab` in order to avoid being carried over the outlet.

If V is the horizontal velocity of the liquid, S the solids particle vertical settling velocity, L the length of the settling device, and D its depth, then particles entering at point A will settle to the bottom of the device only if V does not exceed: S(L/D)Since Vmax / S = L / D then, Vmax = S (L / D)

Therefore, the velocity at which a horizontal clarifying device may be operated successfully is directly proportional to its length and inversely proportional to its depth.

This analysis applies to multiple horizontal plate units also. The spacing between plates is usually a few inches as opposed to a depth of several feet in a horizontal tank; therefore, [settling-out" times are dramatically reduced. The flow must be non-turbulent to prevent settled solids from being re-entrained within the moving liquid. Small plate spacing and a large surface area permits laminar flow at higher velocities than large horizontal tanks would allow.

Horizontal clarifying devices become self-flushing if they are inclined at an angle which exceeds the angle of repose of the settled solids. In such cases, flow enters the lower end of the device where settling particles move to the floor eventually sliding back out the entrance. Clear effluent leaves the top of the device.
However, when the device is inclined, the furthest settling particles no longer fall through distance D but some longer distance D`. This new longer settling distance D` is related to D by the relation: D = D` cos Ø.

Theta [Ø" is the angle, the device is inclined to the horizontal plane. Thus settling distance is increased by the factor: 1/cos Ø In the case where Ø = 60º, 1/cos Ø = 2.

The maximum settling distance is twice the distance between the plates. It is apparent then that the lower the angle of inclination, the smaller the settling distance. However, the angle of inclination must exceed the angle of repose of the solids to be separated. The previous equation may be modified to express the cosine of an inclined plate clarifying system as:
Vmax = L / (D / cosØ) (s) = L·cosØ / D (s)

Inclined Plate Clarifiers
A reduction of the required floor space is acquired by diminishing the separation between the horizontal plates to a few inches and stacking the settling surfaces. Inclining the plates to provide self flushing, 45º for heavy particles and 60º for light particles, reduces the available horizontal projected area (effective settling area) by a factor equivalent to the cosine of the angle. The surface area diagram (below) graphically compares the floor space requirements of an HEI inclined plate clarifier with the equivalent horizontal projected settling area.

Settling Rate
The settling rate for a specific solids should be determined by standard laboratory tests. Light particles, such as metal hydroxides, usually require a design parameter of 0.25 – 0.50 gallons per minute per square foot of horizontal projected area. These low density solids require the inclined plates to be set at a 60º angle to induce the particles to slide down the plate. Heavier particles (such as sand that easily flow) will readily slide from plates set at a 45º angle.

Maximum flow rate of an inclined plate clarifier is based on the flow rate per unit of a horizontally projected surface area. Retention time in the clarifier is not a design criteria. However, attaining optimum performance requires the prudent design to recognize several additional, very important factors.

Inclined plate clarifier, Lanmei inclined plate clarifier, Inclined Tube Settler,High-Efficiency Inclined Tube

Wuxi Feiyiya Environmental Protection Technology Co., Ltd. , https://www.fefinegrille.com