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SEPARATE VACUUM HOPPER LOADER SPECS.
Model # Conveying Capacity (lbs/hr) Motor (HP)
SAL-700G 771 1.6
SAL-810G 661 1
SAL-820G 1058 2
description

The separate vacuum hopper loader is designed for conveying material over long distances. The material hopper is placed away from the main unit while the main unit’s vacuum motor provides continuous superior suction for the material. Each unit incorporates motor overload protection and is fitted with a low material shortage alarm.

MINI CENTRAL LOADING SYSTEMS SPECS.
Model #  Conveing Capacity (lbs) Number of Receivers
SAL-5HP-UG 2,200 1
SAL-5HP-UG-122 3,748 2
SAL-5HP-UG-124 2,645 4
DESCRIPTION

Mini central loading systems from Shini USA are designed to convey the plastic resin and powders from one or more central storage bins to the individual plastic processing machine. All central loaders are filter-less; there is just a central filter in tandem with the vacuum pump.

With easily functioning controls and a rugged design, our 1, 2 and 4 station mini central loading systems will cater to your industrial plastics needs.

single station vacuum receiver SPECS.
Model # Hose Diameter (in) Capacity (lbs)
SHR-6U 1.5 1.5
SHR-12U 1.5 1.5
SHR-24U 2 2
DESCRIPTION

The Shini USA SHR-U and SHR-U-E Receivers are constructed of high quality stainless steel and feature a vacuum sequencing valve.

POWDER CONVEYING CENTRAL SYSTEMS SPECS.
MODEL #  Conveying Capacity (lbs) Motor Power (HP)
SAL-1HP-UGP 600 1
SAL-2HP-UGP 880 2.5
SAL-3HP-UGP 1764 3.5
SAL-5HP-UGP 2650 5.5
DESCRIPTION

The Shini USA Brushless Powder Conveying System SAL-UGP series offers a system for 30% Powder and a system for 100% Powder. The industrial duty components and rugged design will stand up to even the harshest operating conditions.

The Shini USA, Division of Budzar Industries Powder Conveying System designed to convey plastic resins and powders to a single separate station, incorporates one fitted filter in the hopper and another fitted at the vacuum pump thereby effectively removing dust and the issues created by dust.

POWDER CONVEYING CENTRAL SYSTEMS
Model # Conveying Cap. (lbs/hr) Hose Dia.
SHR-P-12U 660 1.5
SHR-P-30U 880 1.5
SHR-P-60U 1 2
SHR-P-90U 1 2.5
DESCRIPTION

The Shini USA SHR-P-U Receivers are constructed of high quality stainless steel and are specifically designed for simple and efficient loading of powder materials.

Calculators

Power Flow Rate Temp Calculator

Calculate the electrical power, flow rate or temperature requirement.
airflow in standard cubic feet per minute
temperature rise in degrees F from the inlet to the exhaust
Watts = SCFM x ΔT/2.5

Temperature Conversion Calculator

Calculate the electrical power, flow rate or temperature requirement.
°F = ((( °C * 9) / 5 ) + 32)
°C = ((( °F - 32) * 5 ) / 9)

Three-Phase Unit Calculator

Fill in two values to find the 3rd.
W = LC * (V * √2)
V = (W / LC) / √2
LC = W / (V * √2)

Single Phase Unit Calculator

Fill in two values to find the 3rd.
W = LC * V
V = LC * W
LC = W / V

Ohms Law Calculator

Fill in two values to find the other two.

O = V / A

O = V² / W

O = W / A²

V = A * O = A * (V/A)

V = √(W * O)

V = W / A

A = V / O

A = W/ V

A = √(W / O)

W = A * V

W = V² / O

W = A² * O

Heat Transfer Through Convection Calculator

ρ = density (lb/ft3)

V = volume flow rate (ft3/hour)

Cp = specific heat (Btu/lb°F)

Ta-Tb = temperature differential (°F)

Q = ρ x V x Cp x (Ta-Tb)


Fill in four values

ρ = density (lb/ft3)
V = volume flow rate (ft3/hour)
Cp = specific heat (Btu/lb°F)
Ta-Tb = TD (°F)
Q = ρ x V x Cp x (Ta-Tb)

ACFM to SCFM

ACFM = airflow in actual cubic feet per minute

P = gage pressure (psi)

T = gas temperature °R = 460 + °F

SCFM = airflow in standard cubic feet per minute


Find Standard Cubic Feet per Minute based on data from your Actual Cubic Feet per Minute Rotameter

airflow in actual cubic feet per minute
gage pressure (psi)
gas temperature °R = 460 + °F
airflow in standard cubic feet per minute

Standard Flow Rate (SCFM) Calculator

Calculate the SCFM.
Actual cubic feet per minute
Actual pounds per square inch at Gauge
Actual temperature in °F. °R = 460 + °F
CFM * (PSI actual / 14.7psi)*(528°R / T actual)

Pressure Conversion

Fill in one value to calculate the other.
PSI = Bar * 14.504
Bar = PSI / 14.504

Mass Flow to volume Metric Flow

Fill in one value to calculate the other two
kg/h = Kilogram Per Hour (lb/min multiply by 27.216)
Lbs/min = Pounds per minute (kg/h divide by 27.216)
SCFM = Standard cubic feet per minute

Power Flow Rate Temp Calculator

Calculate the electrical power, flow rate or temperature requirement.
airflow in standard cubic feet per minute
temperature rise in degrees F from the inlet to the exhaust
Watts = SCFM x ΔT/2.5

Temperature Conversion Calculator

Calculate the electrical power, flow rate or temperature requirement.
°C = ((( °F - 32) * 5 ) / 9)
°F = ((( °C * 9) / 5 ) + 32)

Three-Phase Unit Calculator

Fill in two values to find the 3rd.
W = LC * (V * √2)
V = (W / LC) / √2
LC = W / (V * √2)

Single Phase Unit Calculator

Fill in two values to find the 3rd.
W = LC * V
V = LC * W
LC = W / V

Ohms Law Calculator

Fill in two values to find the other two.

O = V / A

O = V² / W

O = W / A²

V = A * O = A * (V/A)

V = √(W * O)

V = W / A

A = V / O

A = W/ V

A = √(W / O)

W = A * V

W = V² / O

W = A² * O

Heat Transfer Through Convection Calculator

ρ = density (lb/ft3)

V = volume flow rate (ft3/hour)

Cp = specific heat (Btu/lb°F)

Ta-Tb = temperature differential (°F)

Q = ρ x V x Cp x (Ta-Tb)


Fill in four values

ρ = density (lb/ft3)
V = volume flow rate (ft3/hour)
Cp = specific heat (Btu/lb°F)
Ta-Tb = TD (°F)
Q = ρ x V x Cp x (Ta-Tb)

ACFM to SCFM

ACFM = airflow in actual cubic feet per minute

P = gage pressure (psi)

T = gas temperature °R = 460 + °F

SCFM = airflow in standard cubic feet per minute


Find Standard Cubic Feet per Minute based on data from your Actual Cubic Feet per Minute Rotameter

airflow in actual cubic feet per minute
gage pressure (psi)
gas temperature °R = 460 + °F
airflow in standard cubic feet per minute

Standard Flow Rate (SCFM) Calculator

Calculate the SCFM.
Actual cubic feet per minute
Actual pounds per square inch at Gauge
Actual temperature in °F. °R = 460 + °F
CFM * (PSI actual / 14.7psi)*(528°R / T actual)

Pressure Conversion

Fill in one value to calculate the other.
PSI = Bar * 14.504
Bar = PSI / 14.504

Mass Flow to volume Metric Flow

Fill in one value to calculate the other two
Kg/h = Kilogram Per Hour (lb/min multiply by 27.216)
Lbs/min = Pounds per minute (kg/h divide by 27.216)
SCFM = Standard cubic feet per minute