Quality Assurance in PEB - Pre Engineered steel buildingsmbphenix
Quality is main aspect in Pre engineered steel buildings. it is applicable to each and every parameter of PEB design. while manufacturing a PEB , it is essential to maintain QAP. for more details visit http://www.mbphenix.com
Work permit system, By Bimal Chandra Das, safety management, safety tips, sharing of safety knowledge, It is sharing of knowledge. By Bimal Chandra Das, Rtd. AGM (Safety), Bokaro Steel Plant,/ Bokaro. Kolkata
Quality Assurance in PEB - Pre Engineered steel buildingsmbphenix
Quality is main aspect in Pre engineered steel buildings. it is applicable to each and every parameter of PEB design. while manufacturing a PEB , it is essential to maintain QAP. for more details visit http://www.mbphenix.com
Work permit system, By Bimal Chandra Das, safety management, safety tips, sharing of safety knowledge, It is sharing of knowledge. By Bimal Chandra Das, Rtd. AGM (Safety), Bokaro Steel Plant,/ Bokaro. Kolkata
Fire Hydrant System/Sprinkler System Fire Fighting Systems Fire Hydrant Syst...RajyogFireServicesPv
Fire Hydrant System,System Information,Operational Information,Fire Alarm System ......
Being one of the oldest but yet the most effective and common fire fighting solution, a well designed and a well laid out Hydrant System forms the backbone of the entire fire fighting system. It comprises of heavy duty above & underground piping with accessories. External and Fire Escape Hydrant valves are provided at every strategic location. A fire hydrant is a pipe that allows water to flow from a water main with the control of a valve in order to put out a fire.
A fire sprinkler system is an active fire protection measure, consisting of a water supply system, providing adequate pressure and flow rate to a water distribution piping system, onto which fire sprinklers are connected
An automatic sprinkler system is intended to detect, control and extinguish a fire, and warn the occupants of occurrence of fire. The installation comprises fire pumps, water storage tanks, control valve sets, sprinkler heads, flow switches, pressure switches, pipe work and valves. The system operates automatically without human intervention.
6 Excavations (Temporary Works) Risk Assessment Templates
Planned Excavation in areas where live services may be present including:
• Electrical;
• Water;
• Sewerage;
• Gas;
• Telecoms;
PRIOR TO WORKS
Use of Excavator for excavating and backfilling
Excavation open in site area
Confined space working – deep excavations
Maintenance of Excavations
Worker exposure to direct sun
(as applicable)
Insights on Fire Safety Related Requirements in National Building Code (NBC)Consultivo
The presentation on 'Insights on Fire Safety related requirements in National Building Code – NBC' gives an overview of the National Building Code (NBC), requirements related to fire safety and the latest changes. It discusses about the revised NBC rules (NBC 2016 requirements), fire prevention techniques with reference to buildings and also some take home points.
A Silicon-to-System Thermo-Mechanical Review of ElectronicsKamal Karimanal
A Silicon-to-System Review of Thermo-Mechanical Considerations in Electronics
Author: Kamal Karimanal, Cielution LLC
Thermal and Mechanical challenges to IC package reliability has been addressed with a sufficiently working system of information exchange across a supply chain that spans the foundries to system level assembly plants.The never ending market demand for miniaturization, performance, functionality and cost reduction invariably translates to manufacturing, design, assembly, and reliability challenges to the engineer. Within the Thermal and Mechanical realm these challenges manifest to the engineer in the form of seemingly disconnected problems areas such as BEOL yield, flipchip interconnect reliability, warpage mitigation, heat sink retention design, interface choice, thermally aware board and chassis layout, fan sizing and system level optimization. Evolving technology also introduces newer puzzles such as heterogeneous packaging using 3D ICs. The talk will focus on the tools, methodologies and information exchange protocols used by the thermal management and mechanical reliability professionals across the supply chain to address the various challenges.
Fire Hydrant System/Sprinkler System Fire Fighting Systems Fire Hydrant Syst...RajyogFireServicesPv
Fire Hydrant System,System Information,Operational Information,Fire Alarm System ......
Being one of the oldest but yet the most effective and common fire fighting solution, a well designed and a well laid out Hydrant System forms the backbone of the entire fire fighting system. It comprises of heavy duty above & underground piping with accessories. External and Fire Escape Hydrant valves are provided at every strategic location. A fire hydrant is a pipe that allows water to flow from a water main with the control of a valve in order to put out a fire.
A fire sprinkler system is an active fire protection measure, consisting of a water supply system, providing adequate pressure and flow rate to a water distribution piping system, onto which fire sprinklers are connected
An automatic sprinkler system is intended to detect, control and extinguish a fire, and warn the occupants of occurrence of fire. The installation comprises fire pumps, water storage tanks, control valve sets, sprinkler heads, flow switches, pressure switches, pipe work and valves. The system operates automatically without human intervention.
6 Excavations (Temporary Works) Risk Assessment Templates
Planned Excavation in areas where live services may be present including:
• Electrical;
• Water;
• Sewerage;
• Gas;
• Telecoms;
PRIOR TO WORKS
Use of Excavator for excavating and backfilling
Excavation open in site area
Confined space working – deep excavations
Maintenance of Excavations
Worker exposure to direct sun
(as applicable)
Insights on Fire Safety Related Requirements in National Building Code (NBC)Consultivo
The presentation on 'Insights on Fire Safety related requirements in National Building Code – NBC' gives an overview of the National Building Code (NBC), requirements related to fire safety and the latest changes. It discusses about the revised NBC rules (NBC 2016 requirements), fire prevention techniques with reference to buildings and also some take home points.
A Silicon-to-System Thermo-Mechanical Review of ElectronicsKamal Karimanal
A Silicon-to-System Review of Thermo-Mechanical Considerations in Electronics
Author: Kamal Karimanal, Cielution LLC
Thermal and Mechanical challenges to IC package reliability has been addressed with a sufficiently working system of information exchange across a supply chain that spans the foundries to system level assembly plants.The never ending market demand for miniaturization, performance, functionality and cost reduction invariably translates to manufacturing, design, assembly, and reliability challenges to the engineer. Within the Thermal and Mechanical realm these challenges manifest to the engineer in the form of seemingly disconnected problems areas such as BEOL yield, flipchip interconnect reliability, warpage mitigation, heat sink retention design, interface choice, thermally aware board and chassis layout, fan sizing and system level optimization. Evolving technology also introduces newer puzzles such as heterogeneous packaging using 3D ICs. The talk will focus on the tools, methodologies and information exchange protocols used by the thermal management and mechanical reliability professionals across the supply chain to address the various challenges.
Oversizing the HVAC system is detrimental to energy use, comfort, indoor air quality, building and equipment durability. All of these impacts derive from the fact that the system will be “short cycling” in both heating and cooling modes. To reach peak operational efficiency and effectiveness, a heating and cooling system should run for as long as possible to address the loads. Short cycling limits the total amount of air circulating through each room, and can lead to rooms that do not receive adequate duration of airflow. In the cooling season in humid climates, cold clammy conditions can occur due to reduced dehumidification caused by the short cycling of the equipment. The system must run long enough for the coil to reach the temperature for condensation to occur and an oversized system that short cycles may not run long enough to sufficiently condense moisture from the air. Excess humidity in the conditioned air delivered to a space may lead to mold growth within the house.
This "Deep Into Prometheus" talk is the second part of our Prometheus & Monitoring series that is heavily built on the content from the Part I "Dip into Prometheus" webinar. It's strongly recommended to watch the Part I recording first is you missed it: https://youtu.be/lvogDmRN-Hs
In the "Deep Into Prometheus" meetup, I'm going deep into the Prometheus metrics data model. He will delve into how to design high-quality monitoring metrics and consume that data using PromQL while outlining how to avoid common "gotchas" while doing so.
Having 7years’Experience in various angels of MEP with consultant back ground from 05-06-2012 to till Date working as.Associate HVAC Engineer,(MEP Draftsman,Coordinator,Quantity Surveyor), in Green design Engineering Consultant. OMEGASTAR Electromechnical LLC DUBAI-, ADVANCE TECH Electromechnical System DUBAI
The present work is the numerical investigation of Spark Ignition (SI) engines to
assess the effect of spark plug positions using open source Computational Fluid Dynamics
(CFD) tool, OpenFoam is used. The standard k—ε turbulence model is used along with
the Reynolds Averaged Navier Stokes equations for simulating the flow field. Average
piston pressure is tracked for different Crank Angles (CA) from −180o to 180o for two
different sized engines (560cc and 70cc). Results clearly show that spark plug position
affects power output of engine. Spark plug position affect p-θ graph, hence performance
of engine, this effect is dominant in bigger engine than smaller one. Spark plug position
is expressed in dimensionless form in fraction away from centre
Hybrid optimization of pumped hydro system and solar- Engr. Abdul-Azeez.pdffxintegritypublishin
Advancements in technology unveil a myriad of electrical and electronic breakthroughs geared towards efficiently harnessing limited resources to meet human energy demands. The optimization of hybrid solar PV panels and pumped hydro energy supply systems plays a pivotal role in utilizing natural resources effectively. This initiative not only benefits humanity but also fosters environmental sustainability. The study investigated the design optimization of these hybrid systems, focusing on understanding solar radiation patterns, identifying geographical influences on solar radiation, formulating a mathematical model for system optimization, and determining the optimal configuration of PV panels and pumped hydro storage. Through a comparative analysis approach and eight weeks of data collection, the study addressed key research questions related to solar radiation patterns and optimal system design. The findings highlighted regions with heightened solar radiation levels, showcasing substantial potential for power generation and emphasizing the system's efficiency. Optimizing system design significantly boosted power generation, promoted renewable energy utilization, and enhanced energy storage capacity. The study underscored the benefits of optimizing hybrid solar PV panels and pumped hydro energy supply systems for sustainable energy usage. Optimizing the design of solar PV panels and pumped hydro energy supply systems as examined across diverse climatic conditions in a developing country, not only enhances power generation but also improves the integration of renewable energy sources and boosts energy storage capacities, particularly beneficial for less economically prosperous regions. Additionally, the study provides valuable insights for advancing energy research in economically viable areas. Recommendations included conducting site-specific assessments, utilizing advanced modeling tools, implementing regular maintenance protocols, and enhancing communication among system components.
Cosmetic shop management system project report.pdfKamal Acharya
Buying new cosmetic products is difficult. It can even be scary for those who have sensitive skin and are prone to skin trouble. The information needed to alleviate this problem is on the back of each product, but it's thought to interpret those ingredient lists unless you have a background in chemistry.
Instead of buying and hoping for the best, we can use data science to help us predict which products may be good fits for us. It includes various function programs to do the above mentioned tasks.
Data file handling has been effectively used in the program.
The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...Dr.Costas Sachpazis
Terzaghi's soil bearing capacity theory, developed by Karl Terzaghi, is a fundamental principle in geotechnical engineering used to determine the bearing capacity of shallow foundations. This theory provides a method to calculate the ultimate bearing capacity of soil, which is the maximum load per unit area that the soil can support without undergoing shear failure. The Calculation HTML Code included.
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)MdTanvirMahtab2
This presentation is about the working procedure of Shahjalal Fertilizer Company Limited (SFCL). A Govt. owned Company of Bangladesh Chemical Industries Corporation under Ministry of Industries.
Using recycled concrete aggregates (RCA) for pavements is crucial to achieving sustainability. Implementing RCA for new pavement can minimize carbon footprint, conserve natural resources, reduce harmful emissions, and lower life cycle costs. Compared to natural aggregate (NA), RCA pavement has fewer comprehensive studies and sustainability assessments.
CW RADAR, FMCW RADAR, FMCW ALTIMETER, AND THEIR PARAMETERSveerababupersonal22
It consists of cw radar and fmcw radar ,range measurement,if amplifier and fmcw altimeterThe CW radar operates using continuous wave transmission, while the FMCW radar employs frequency-modulated continuous wave technology. Range measurement is a crucial aspect of radar systems, providing information about the distance to a target. The IF amplifier plays a key role in signal processing, amplifying intermediate frequency signals for further analysis. The FMCW altimeter utilizes frequency-modulated continuous wave technology to accurately measure altitude above a reference point.
Saudi Arabia stands as a titan in the global energy landscape, renowned for its abundant oil and gas resources. It's the largest exporter of petroleum and holds some of the world's most significant reserves. Let's delve into the top 10 oil and gas projects shaping Saudi Arabia's energy future in 2024.
HEAP SORT ILLUSTRATED WITH HEAPIFY, BUILD HEAP FOR DYNAMIC ARRAYS.
Heap sort is a comparison-based sorting technique based on Binary Heap data structure. It is similar to the selection sort where we first find the minimum element and place the minimum element at the beginning. Repeat the same process for the remaining elements.
Overview of the fundamental roles in Hydropower generation and the components involved in wider Electrical Engineering.
This paper presents the design and construction of hydroelectric dams from the hydrologist’s survey of the valley before construction, all aspects and involved disciplines, fluid dynamics, structural engineering, generation and mains frequency regulation to the very transmission of power through the network in the United Kingdom.
Author: Robbie Edward Sayers
Collaborators and co editors: Charlie Sims and Connor Healey.
(C) 2024 Robbie E. Sayers
AKS UNIVERSITY Satna Final Year Project By OM Hardaha.pdf
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6. 2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Building Analysis Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
Design Conditions
Location: CoolingHeatingIndoor:
7570Indoor temperature (°F)Chicago Midway AP, IL, US
1566Design TD (°F)ft617Elevation:
5030Relative humidity (%)°N42Latitude:
Outdoor: 34.127.8Moisture difference (gr/lb)CoolingHeating
Infiltration:904Dry bulb (°F)
SimplifiedMethod)L(16-Daily range (°F)
AverageConstruction quality73-Wet bulb (°F)
2 (Average)Fireplaces7.515.0Wind speed (mph)
Heating
Walls
Glazing
Other
Ceilings
Floors
Infiltration
Ducts
Ventilation
% of loadBtuhBtuh/ft²Component
14.260334.3Walls
13.5573523.0Glazing
0.835917.1Doors
7.833101.7Ceilings
8.636321.91.9Floors
22.997195.8Infiltration
26.611276Ducts
00Piping
00Humidification
5.52335Ventilation
0Adjustments
100.042397Total
Cooling
Walls
Glazing
Other
Ceilings Floors
Infiltration
Ducts
Internal Gains
Ventilation
% of loadBtuhBtuh/ft²Component
6.811250.8Walls
30.9508020.4Glazing
0.91547.3Doors
12.820981.1Ceilings
4.98070.4Floors
5.69140.5Infiltration
22.13638Ducts
3.2519Ventilation
12.92120Internal gains
00Blower
0Adjustments
100.016454Total
Latent Cooling Load = 4609 Btuh
Overall U-value = 0.054 Btuh/ft²-°F
Data entries checked.
7. 2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
AED Assessment Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
Design Conditions
Location: CoolingHeatingIndoor:
7570Indoor temperature (°F)Chicago Midway AP, IL, US
1566Design TD (°F)ft617Elevation:
5030Relative humidity (%)°N42Latitude:
Outdoor: 34.127.8Moisture difference (gr/lb)CoolingHeating
Infiltration:904Dry bulb (°F)
)L(16-Daily range (°F)
73-Wet bulb (°F)
7.515.0Wind speed (mph)
Test for Adequate Exposure Diversity
Hourly Glazing Load
Hourly Average AED limit
Glazingload(Btuh)
Hour of Day
0
1,000
2,000
3,000
4,000
5,000
6,000
7,000
8,000
8 9 10 11 12 13 14 15 16 17 18 19 20
Maximum hourly glazing load exceeds average by 20.3%.
House has adequate exposure diversity (AED), based on AED limit of 30%.
AED excursion: 0 Btuh
8. 2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Component Constructions Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
Design Conditions
Location: CoolingHeatingIndoor:
7570Indoor temperature (°F)Chicago Midway AP, IL, US
1566Design TD (°F)ft617Elevation:
5030Relative humidity (%)°N42Latitude:
Outdoor: 34.127.8Moisture difference (gr/lb)CoolingHeating
Infiltration:904Dry bulb (°F)
SimplifiedMethod)L(16-Daily range (°F)
AverageConstruction quality73-Wet bulb (°F)
2 (Average)Fireplaces7.515.0Wind speed (mph)
Construction descriptions GainLoss Clg HTMHtg HTMInsul RU-valueAreaOr
BtuhBtuh/ft²BtuhBtuh/ft²ft²-°F/BtuhBtuh/ft²-°Fft²
Walls
12F-0bw: Frm wall, brk 4" ext, 1/2" wood shth, r-21 cav ins, 1/2"
gypsum board int fnsh, 2"x6" wood frm
3760.8020144.2721.00.065472n
1860.809994.2721.00.065234e
3720.8019964.2721.00.065467s
1910.8010234.2721.00.065240w
11250.8060334.2721.00.0651413all
Partitions
(none)
Windows
10D-c: 2 glazing, clr low-e outr, air gas, clad wd frm mat, clr innr, 1/4"
gap, 1/8" thk; NFRC rated (SHGC=0.31)
4217.73125123.000.35054n
40311.083923.000.35037n
154134.2103523.000.35045e
136918.5170523.000.35074s
134734.290423.000.35039w
508020.4573523.000.350249all
Doors
11E0: Door, wd sc type, wd strm 1547.3235917.100.26021s
Ceilings
16C-38aw: Attic ceiling, asphalt shingles roof mat, r-38 ceil ins, 1/2"
gypsum board int fnsh
20981.0833101.7138.00.0261938
Floors
19A-30bstp: Flr floor, frm flr, 10" thkns, r-30 cav ins, tight bsmt ovr 0.4236321.8730.00.0341938 807
9. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Load Short Form Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
Design Information
InfiltrationClgHtg
SimplifiedMethod904Outside db (°F)
AverageConstruction quality7570Inside db (°F)
2 (Average)Fireplaces1566Design TD (°F)
L-Daily range
5030Inside humidity (%)
3428Moisture difference (gr/lb)
HEATING EQUIPMENT COOLING EQUIPMENT
Make Goodman Mfg. Make Goodman Mfg.
Trade GOODMAN Trade GOODMAN
Model GCH950453BX** Cond SSX160241B*
AHRI ref 3653909 Coil CA*F3636*6D*
AHRI ref 4652177
Efficiency 95 AFUE Efficiency 13.2 EER, 16 SEER
Heating input Btuh46000 Sensible cooling Btuh18720
Heating output Btuh44000 Latent cooling Btuh5280
Temperature rise °F51 Total cooling Btuh24000
Actual air flow cfm800 Actual air flow cfm800
Air flow factor cfm/Btuh0.020 Air flow factor cfm/Btuh0.050
Static pressure in H2O0.60 Static pressure in H2O0.60
Space thermostat Load sensible heat ratio 0.78
ROOM NAME Area Htg load Clg load Htg AVF Clg AVF
(ft²) (Btuh) (Btuh) (cfm) (cfm)
Master Bedroom 240 7575 2618 151 131
Master Bath 112 2734 590 55 30
Master Wic 98 0 0 0 0
Den 150 2507 644 50 32
Dining 129 2095 506 42 25
Kitchen 176 4861 3265 97 164
Living Room 394 9296 4527 186 227
CL 2 34 0 0 0 0
Bedroom 2 192 5733 2242 114 113
Hall 126 0 0 0 0
Bath 2 90 1481 312 30 16
Bedroom 3 198 3780 1232 75 62
10. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 2
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
Entire House d 1939 40063 15935 800 800
Other equip loads 2335 519
Equip. @ 1.00 RSM 16454
Latent cooling 4609
TOTALS 1939 42397 21064 800 800
11. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name Entire House Master Bedroom
2 Exposed wall 187.0 ft 31.0 ft
3 Room height 9.0 dft 9.0 heat/coolft
4 Room dimensions ft15.0x16.0
5 Room area 1938.9 ft² 240.0 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area (ft²) Load
number (Btuh/ft²-°F)(Btuh/ft²-°F) (Btuh/ft²)(Btuh/ft²) or perimeter (ft) (Btuh) or perimeter (ft) (Btuh)
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 WW 12F-0bw12F-0bw 0.0650.065 nn 4.274.27 0.800.80 563 472 2014 376 144 90 383 71
. GG 10D-c10D-c 0.3500.350 nn 22.9922.99 7.737.73 54 0 1251 421 54 0 1251 421
. GG 4A5-2oc4A5-2oc 0.3500.350 nn 22.9922.99 11.0511.05 37 0 839 403 0 0 0 0
. WW 12F-0bw12F-0bw 0.0650.065 ee 4.274.27 0.800.80 279 234 999 186 0 0 0 0
11 GG 4A5-2oc4A5-2oc 0.3500.350 ee 22.9922.99 34.2434.24 45 0 1035 1541 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ss 4.274.27 0.800.80 563 467 1996 372 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ss 22.9922.99 18.4618.46 74 0 1705 1369 0 0 0 0
DD 11E011E0 0.2600.260 ss 17.0817.08 7.327.32 21 21 359 154 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ww 4.274.27 0.800.80 279 240 1023 191 135 115 493 92
GG 4A5-2oc4A5-2oc 0.3500.350 ww 22.9922.99 34.2434.24 39 0 904 1347 20 0 452 673
CC 16C-38aw16C-38aw 0.0260.026 -- 1.711.71 1.081.08 1938 1938 3310 2098 240 240 410 260
FF 19A-30bstp19A-30bstp 0.0340.034 -- 1.871.87 0.420.42 1938 1938 3632 807 240 240 450 100
6 c) AED excursion 0 144
Envelope loss/gain 19068 9264 3438 1761
12 a) Infiltration 9719 914 1611 151
b) Room ventilation 0 0 0 0
13 Internal gains: Occupants @ 230230 4 920 0 0
Appliances/other 1200 0
Subtotal (lines 6 to 13) 28787 12298 5049 1912
Less external loadLess external load 0 0 0 0
Less transferLess transfer 0 0 0 0
RedistributionRedistribution 0 0 393 108
14 Subtotal 28787 12298 5443 2020
15 Duct loads 39% 30% 11276 3638 39% 30% 2132 598
Total room load 40063 15935 7575 2618
Air required (cfm)Air required (cfm) 800 800 151 131
12. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 2
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name Master Bath Master Wic
2 Exposed wall 14.0 ft 0 ft
3 Room height 9.0 heat/coolft 9.0 heat/coolft
4 Room dimensions ft8.0x14.0 ft7.0x14.0
5 Room area 112.0 ft² 98.0 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area (ft²) Load
number (Btuh/ft²-°F)(Btuh/ft²-°F) (Btuh/ft²)(Btuh/ft²) or perimeter (ft) (Btuh) or perimeter (ft) (Btuh)
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 WW 12F-0bw12F-0bw 0.0650.065 nn 4.274.27 0.800.80 126 120 510 95 0 0 0 0
. GG 10D-c10D-c 0.3500.350 nn 22.9922.99 7.737.73 0 0 0 0 0 0 0 0
. GG 4A5-2oc4A5-2oc 0.3500.350 nn 22.9922.99 11.0511.05 7 0 149 72 0 0 0 0
. WW 12F-0bw12F-0bw 0.0650.065 ee 4.274.27 0.800.80 0 0 0 0 0 0 0 0
11 GG 4A5-2oc4A5-2oc 0.3500.350 ee 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ss 4.274.27 0.800.80 0 0 0 0 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ss 22.9922.99 18.4618.46 0 0 0 0 0 0 0 0
DD 11E011E0 0.2600.260 ss 17.0817.08 7.327.32 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ww 4.274.27 0.800.80 0 0 0 0 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ww 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
CC 16C-38aw16C-38aw 0.0260.026 -- 1.711.71 1.081.08 112 112 191 121 98 98 167 106
FF 19A-30bstp19A-30bstp 0.0340.034 -- 1.871.87 0.420.42 112 112 210 47 98 98 184 41
6 c) AED excursion -18 -7
Envelope loss/gain 1061 317 351 140
12 a) Infiltration 728 68 0 0
b) Room ventilation 0 0 0 0
13 Internal gains: Occupants @ 230230 0 0 0 0
Appliances/other 0 0
Subtotal (lines 6 to 13) 1789 385 351 140
Less external loadLess external load 0 0 0 0
Less transferLess transfer 0 0 0 0
RedistributionRedistribution 176 70 -351 -140
14 Subtotal 1964 455 0 0
15 Duct loads 39% 30% 769 135 39% 30% 0 0
Total room load 2734 590 0 0
Air required (cfm)Air required (cfm) 55 30 0 0
13. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 3
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name Den Dining
2 Exposed wall 10.0 ft 9.5 ft
3 Room height 9.0 heat/coolft 9.0 heat/coolft
4 Room dimensions ft15.0x10.0 ft13.6x9.5
5 Room area 150.0 ft² 128.8 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area (ft²) Load
number (Btuh/ft²-°F)(Btuh/ft²-°F) (Btuh/ft²)(Btuh/ft²) or perimeter (ft) (Btuh) or perimeter (ft) (Btuh)
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 WW 12F-0bw12F-0bw 0.0650.065 nn 4.274.27 0.800.80 90 80 342 64 86 76 322 60
. GG 10D-c10D-c 0.3500.350 nn 22.9922.99 7.737.73 0 0 0 0 0 0 0 0
. GG 4A5-2oc4A5-2oc 0.3500.350 nn 22.9922.99 11.0511.05 10 0 230 110 10 0 230 110
. WW 12F-0bw12F-0bw 0.0650.065 ee 4.274.27 0.800.80 0 0 0 0 0 0 0 0
11 GG 4A5-2oc4A5-2oc 0.3500.350 ee 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ss 4.274.27 0.800.80 0 0 0 0 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ss 22.9922.99 18.4618.46 0 0 0 0 0 0 0 0
DD 11E011E0 0.2600.260 ss 17.0817.08 7.327.32 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ww 4.274.27 0.800.80 0 0 0 0 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ww 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
CC 16C-38aw16C-38aw 0.0260.026 -- 1.711.71 1.081.08 150 150 256 162 128 128 219 139
FF 19A-30bstp19A-30bstp 0.0340.034 -- 1.871.87 0.420.42 150 150 281 62 128 128 240 53
6 c) AED excursion -20 -19
Envelope loss/gain 1109 379 1012 344
12 a) Infiltration 520 49 494 46
b) Room ventilation 0 0 0 0
13 Internal gains: Occupants @ 230230 0 0 0 0
Appliances/other 0 0
Subtotal (lines 6 to 13) 1629 428 1506 391
Less external loadLess external load 0 0 0 0
Less transferLess transfer 0 0 0 0
RedistributionRedistribution 173 69 0 0
14 Subtotal 1802 497 1506 391
15 Duct loads 39% 30% 706 147 39% 30% 590 116
Total room load 2507 644 2095 506
Air required (cfm)Air required (cfm) 50 32 42 25
14. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 4
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name Kitchen Living Room
2 Exposed wall 26.5 ft 40.0 ft
3 Room height 9.0 heat/coolft 9.0 heat/coolft
4 Room dimensions ft13.6x13.0 ft17.5x22.5
5 Room area 176.3 ft² 393.8 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area (ft²) Load
number (Btuh/ft²-°F)(Btuh/ft²-°F) (Btuh/ft²)(Btuh/ft²) or perimeter (ft) (Btuh) or perimeter (ft) (Btuh)
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 WW 12F-0bw12F-0bw 0.0650.065 nn 4.274.27 0.800.80 117 107 457 85 0 0 0 0
. GG 10D-c10D-c 0.3500.350 nn 22.9922.99 7.737.73 0 0 0 0 0 0 0 0
. GG 4A5-2oc4A5-2oc 0.3500.350 nn 22.9922.99 11.0511.05 10 0 230 110 0 0 0 0
. WW 12F-0bw12F-0bw 0.0650.065 ee 4.274.27 0.800.80 122 107 455 85 158 128 544 102
11 GG 4A5-2oc4A5-2oc 0.3500.350 ee 22.9922.99 34.2434.24 15 0 345 514 30 0 690 1027
WW 12F-0bw12F-0bw 0.0650.065 ss 4.274.27 0.800.80 0 0 0 0 203 139 595 111
GG 4A5-2oc4A5-2oc 0.3500.350 ss 22.9922.99 18.4618.46 0 0 0 0 42 0 968 777
DD 11E011E0 0.2600.260 ss 17.0817.08 7.327.32 0 0 0 0 21 21 359 154
WW 12F-0bw12F-0bw 0.0650.065 ww 4.274.27 0.800.80 0 0 0 0 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ww 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
CC 16C-38aw16C-38aw 0.0260.026 -- 1.711.71 1.081.08 176 176 300 190 394 394 673 426
FF 19A-30bstp19A-30bstp 0.0340.034 -- 1.871.87 0.420.42 176 176 329 73 394 394 738 164
6 c) AED excursion -97 -166
Envelope loss/gain 2115 961 4567 2595
12 a) Infiltration 1377 129 2079 195
b) Room ventilation 0 0 0 0
13 Internal gains: Occupants @ 230230 1 230 3 690
Appliances/other 1200 0
Subtotal (lines 6 to 13) 3493 2520 6646 3480
Less external loadLess external load 0 0 0 0
Less transferLess transfer 0 0 0 0
RedistributionRedistribution 0 0 34 14
14 Subtotal 3493 2520 6680 3494
15 Duct loads 39% 30% 1368 745 39% 30% 2617 1033
Total room load 4861 3265 9296 4527
Air required (cfm)Air required (cfm) 97 164 186 227
15. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 5
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name CL 2 Bedroom 2
2 Exposed wall 4.0 ft 28.0 ft
3 Room height 9.0 heat/coolft 9.0 heat/coolft
4 Room dimensions ft4.0x8.5 ft12.0x16.0
5 Room area 34.0 ft² 192.0 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area (ft²) Load
number (Btuh/ft²-°F)(Btuh/ft²-°F) (Btuh/ft²)(Btuh/ft²) or perimeter (ft) (Btuh) or perimeter (ft) (Btuh)
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 WW 12F-0bw12F-0bw 0.0650.065 nn 4.274.27 0.800.80 0 0 0 0 0 0 0 0
. GG 10D-c10D-c 0.3500.350 nn 22.9922.99 7.737.73 0 0 0 0 0 0 0 0
. GG 4A5-2oc4A5-2oc 0.3500.350 nn 22.9922.99 11.0511.05 0 0 0 0 0 0 0 0
. WW 12F-0bw12F-0bw 0.0650.065 ee 4.274.27 0.800.80 0 0 0 0 0 0 0 0
11 GG 4A5-2oc4A5-2oc 0.3500.350 ee 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ss 4.274.27 0.800.80 0 0 0 0 144 132 563 105
GG 4A5-2oc4A5-2oc 0.3500.350 ss 22.9922.99 18.4618.46 0 0 0 0 12 0 278 223
DD 11E011E0 0.2600.260 ss 17.0817.08 7.327.32 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ww 4.274.27 0.800.80 36 36 154 29 108 88 377 70
GG 4A5-2oc4A5-2oc 0.3500.350 ww 22.9922.99 34.2434.24 0 0 0 0 20 0 452 673
CC 16C-38aw16C-38aw 0.0260.026 -- 1.711.71 1.081.08 34 34 58 37 192 192 328 208
FF 19A-30bstp19A-30bstp 0.0340.034 -- 1.871.87 0.420.42 34 34 64 14 192 192 360 80
6 c) AED excursion -5 161
Envelope loss/gain 276 75 2359 1521
12 a) Infiltration 208 20 1455 137
b) Room ventilation 0 0 0 0
13 Internal gains: Occupants @ 230230 0 0 0 0
Appliances/other 0 0
Subtotal (lines 6 to 13) 483 95 3814 1657
Less external loadLess external load 0 0 0 0
Less transferLess transfer 0 0 0 0
RedistributionRedistribution -483 -95 306 73
14 Subtotal 0 0 4119 1730
15 Duct loads 39% 30% 0 0 39% 30% 1614 512
Total room load 0 0 5733 2242
Air required (cfm)Air required (cfm) 0 0 114 113
16. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 6
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name Hall Bath 2
2 Exposed wall 0 ft 7.5 ft
3 Room height 9.0 heat/coolft 9.0 heat/coolft
4 Room dimensions ft4.0x31.5 ft12.0x7.5
5 Room area 126.0 ft² 90.0 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area (ft²) Load
number (Btuh/ft²-°F)(Btuh/ft²-°F) (Btuh/ft²)(Btuh/ft²) or perimeter (ft) (Btuh) or perimeter (ft) (Btuh)
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 WW 12F-0bw12F-0bw 0.0650.065 nn 4.274.27 0.800.80 0 0 0 0 0 0 0 0
. GG 10D-c10D-c 0.3500.350 nn 22.9922.99 7.737.73 0 0 0 0 0 0 0 0
. GG 4A5-2oc4A5-2oc 0.3500.350 nn 22.9922.99 11.0511.05 0 0 0 0 0 0 0 0
. WW 12F-0bw12F-0bw 0.0650.065 ee 4.274.27 0.800.80 0 0 0 0 0 0 0 0
11 GG 4A5-2oc4A5-2oc 0.3500.350 ee 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ss 4.274.27 0.800.80 0 0 0 0 68 68 288 54
GG 4A5-2oc4A5-2oc 0.3500.350 ss 22.9922.99 18.4618.46 0 0 0 0 0 0 0 0
DD 11E011E0 0.2600.260 ss 17.0817.08 7.327.32 0 0 0 0 0 0 0 0
WW 12F-0bw12F-0bw 0.0650.065 ww 4.274.27 0.800.80 0 0 0 0 0 0 0 0
GG 4A5-2oc4A5-2oc 0.3500.350 ww 22.9922.99 34.2434.24 0 0 0 0 0 0 0 0
CC 16C-38aw16C-38aw 0.0260.026 -- 1.711.71 1.081.08 126 126 215 136 90 90 154 97
FF 19A-30bstp19A-30bstp 0.0340.034 -- 1.871.87 0.420.42 126 126 236 52 90 90 169 37
6 c) AED excursion -9 -10
Envelope loss/gain 451 180 611 178
12 a) Infiltration 0 0 390 37
b) Room ventilation 0 0 0 0
13 Internal gains: Occupants @ 230230 0 0 0 0
Appliances/other 0 0
Subtotal (lines 6 to 13) 451 180 1001 215
Less external loadLess external load 0 0 0 0
Less transferLess transfer 0 0 0 0
RedistributionRedistribution -451 -180 64 26
14 Subtotal 0 0 1064 241
15 Duct loads 39% 30% 0 0 39% 30% 417 71
Total room load 0 0 1481 312
Air required (cfm)Air required (cfm) 0 0 30 16
17. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:50
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 7
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Right-J® Worksheet Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
1 Room name Bedroom 3
2 Exposed wall 16.5 ft
3 Room height 9.0 heat/coolft
4 Room dimensions ft12.0x16.5
5 Room area 198.0 ft²
Ty Construction U-value Or HTM Area (ft²) Load Area Load
number (Btuh/ft²-°F) (Btuh/ft²) or perimeter (ft) (Btuh) or perimeter
Heat Cool Gross N/P/S Heat Cool Gross N/P/S Heat Cool
6 W 12F-0bw 0.065 n 4.27 0.80 0 0 0 0
. G 10D-c 0.350 n 22.99 7.73 0 0 0 0
. G 4A5-2oc 0.350 n 22.99 11.05 0 0 0 0
. W 12F-0bw 0.065 e 4.27 0.80 0 0 0 0
11 G 4A5-2oc 0.350 e 22.99 34.24 0 0 0 0
W 12F-0bw 0.065 s 4.27 0.80 149 129 549 102
G 4A5-2oc 0.350 s 22.99 18.46 20 0 460 369
D 11E0 0.260 s 17.08 7.32 0 0 0 0
W 12F-0bw 0.065 w 4.27 0.80 0 0 0 0
G 4A5-2oc 0.350 w 22.99 34.24 0 0 0 0
C 16C-38aw 0.026 - 1.71 1.08 198 198 338 214
F 19A-30bstp 0.034 - 1.87 0.42 198 198 371 82
6 c) AED excursion 45
Envelope loss/gain 1718 814
12 a) Infiltration 858 81
b) Room ventilation 0 0
13 Internal gains: Occupants @ 230 0 0
Appliances/other 0
Subtotal (lines 6 to 13) 2576 895
Less external load 0 0
Less transfer 0 0
Redistribution 141 56
14 Subtotal 2716 951
15 Duct loads 39% 30% 1064 281
Total room load 3780 1232
Air required (cfm) 75 62
18. Calculations approved by ACCA to meet all requirements of Manual J 8th Ed.
2014-Mar-18 18:55:54
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Project Summary Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
Joe Contractor
Superior HVAC
Notes:
Design Information
Chicago Midway AP, IL, USWeather:
Winter Design Conditions Summer Design Conditions
Outside db °F4 Outside db °F90
Inside db °F70 Inside db °F75
Design TD °F66 Design TD °F15
Daily range L
Relative humidity %50
Moisture difference gr/lb34
Heating Summary Sensible Cooling Equipment Load Sizing
Structure Btuh28787 Structure Btuh12298
Ducts Btuh11276 Ducts Btuh3638
Central vent (33 cfm) 2335 Btuh Central vent (33 cfm) Btuh519
Humidification Btuh0 Blower Btuh0
Piping Btuh0
Equipment load Btuh42397 Use manufacturer's data y
Rate/swing multiplier 1.00
Infiltration Equipment sensible load Btuh16454
Method Latent Cooling Equipment Load SizingSimplified
Construction quality Average
2 (Average)Fireplaces Structure Btuh2120
Ducts Btuh1740
CoolingHeating Central vent (33 cfm) Btuh750
19391939Area (ft²) Equipment latent load Btuh4609
1745017450Volume (ft³)
Air changes/hour 0.200.47 Equipment total load Btuh21064
Equiv. AVF (cfm) 58138 Req. total capacity at 0.78 SHR ton1.8
Heating Equipment Summary Cooling Equipment Summary
Make Goodman Mfg. Make Goodman Mfg.
Trade GOODMAN Trade GOODMAN
Model GCH950453BX** Cond SSX160241B*
AHRI ref 3653909 Coil CA*F3636*6D*
AHRI ref 4652177
Efficiency 95 AFUE Efficiency 13.2 EER, 16 SEER
Heating input Btuh46000 Sensible cooling Btuh18720
Heating output Btuh44000 Latent cooling Btuh5280
Temperature rise °F51 Total cooling Btuh24000
Actual air flow cfm800 Actual air flow cfm800
Air flow factor cfm/Btuh0.020 Air flow factor cfm/Btuh0.050
Static pressure in H2O0.60 Static pressure in H2O0.60
Space thermostat Load sensible heat ratio 0.78
19. 2014-Mar-18 18:55:54
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Manual S Compliance Report Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
Cooling Equipment
Design Conditions
°F77.0Entering coil DB:Btuh16454Sensible gain:°F89.6Outdoor design DB:
°F64.1Entering coil WB:Btuh4609Latent gain:°F73.3Outdoor design WB:
Btuh21064Total gain:°F75.0Indoor design DB:
cfm800Estimated airflow:%50Indoor RH:
Manufacturer's Performance Data at Actual Design Conditions
Split ACEquipment type:
SSX160241B*+CA*F3636*6D*Model:Goodman Mfg.Manufacturer:
cfm800Actual airflow:
% of load110Btuh18121Sensible capacity:
% of load106Btuh4900Latent capacity:
%79SHR:% of load109Btuh23021Total capacity:
Heating Equipment
Design Conditions
°F60.8Entering coil DB:Btuh42397Heat loss:°F4.3Outdoor design DB:
°F70.0Indoor design DB:
Manufacturer's Performance Data at Actual Design Conditions
Gas furnaceEquipment type:
GCH950453BX**Model:Goodman Mfg.Manufacturer:
cfm800Actual airflow:
°F50Temp. rise:% of load104Btuh44000Output capacity:
The above equipment was selected in accordance with ACCA Manual S.
20. Right-Suite® Universal 2013 13.0.09 RSU13868
Form
RPER 1
15 Mar 09
Residential Plans Examiner Review Form
for HVAC System Design (Loads, Equipment, Ducts)
Header Information
Contractor: ATTACHEDREQUIRED ATTACHMENTSSavoy Engineering Group
NoYesManual J1 Form (and supporting worksheets):
Mechanical license: NoYesor MJ1AE Form* (and supporting worksheets):
NoYesOEM performance data (heating, cooling, blower):
Building plan #: NoYesManual D Friction Rate Worksheet:
NoYesDuct distribution sketch:
Home address (Street or Lot#, Block, Subdivision): ACCA Manual J Street, Entire House
HVAC LOAD CALCULATION (IRC M1401.3)
Design Conditions Building Construction Information
Front Door faces South
BuildingWinter Design Conditions
North, East, West, South, Northeast, Northwest, Southeast, Southwest
Orientation:°F4Outdoor temperature:
°F70Indoor temperature:
3Number of bedrooms:Btuh42397Total heat loss:
ft²1939Conditioned floor area:
4Number of occupants:Summer Design Conditions
°F90Outdoor temperature:
Windows°F75Indoor temperature:
ft0Eave overhang depth:% RH50gr/lb @34Grains difference:
Blinds, drapes, etc.
noneInternal shade:Btuh16454Sensible heat gain:
Btuh4609Latent heat gain:
0Number of skylights:Btuh21064Total heat gain:
HVAC EQUIPMENT SELECTION (IRC M1401.3)
Heating Equipment Data Blower DataCooling Equipment Data
800Heating cfm:
Air Conditioner, Heat pump, etc.
Split ACEquipment type:
Furnace, Heat pump, Boiler, etc.
Gas furnaceEquipment type:
800Cooling cfm:
Fan's rated external static pressure for design
airflow
in H2O0.60Static pressure:Goodman Mfg.Model:Goodman Mfg.Model:
GCH950453BX**+ SSX160241B*+CA*F3636*6D*
Btuh23021Total cooling capacity:
Heat pumps - capacity at winter design outdoor conditions
Btuh44000Heating output capacity:
Btuh18121Sensible cooling capacity:
Btuh4900Latent cooling capacity:Btuh0Aux. heating output capacity:
HVAC DUCT DISTRIBUTION SYSTEM DESIGN (IRC M1601.1)
Duct Materials Usedft232Longest supply duct:cfm800Design airflow:
Sheet metalTrunk duct:ft197Longest return duct:in H2O0.60Equipment design ESP:
ft429Total effective length (TEL):in H2O-0.3Total device pressure losses:
Round flex vinyl, Sheet metalBranch duct:
Friction Rate = ASP ÷ (TELx 100)
in/100ft0.077Friction rate:in H2O0.33Available static pressure (ASP):
I declare the load calculation, equipment, equipment selection and duct design were rigorously performed based on the building plan
listed above. I understand the claims made on these forms will be subject to review and verification.
Contractor's printed name:
Contractor's signature: Date:
Reserved for County, Town Municipality or Authority having jurisdiction use.
*Home qualifies for MJ1AE Form based on Abridged Edition Checklist
21. 2014-Mar-18 18:55:54
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 1
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
SEG 0314-077WJob:
Duct System Summary Mar 17, 2014Date:
Entire House Tracy SavoyBy:
Savoy Engineering Group
Phone: (801) 949-5337 Web: www.load-calculations.com
Project Information
Right-Sized ResidenceFor:
ACCA Manual J Street, Oak Park, IL 60301
CoolingHeating
External static pressure in H2O0.60in H2O0.60
Pressure losses in H2O0.27in H2O0.27
Available static pressure in H2O0.33in H2O0.33
Supply / return available pressure 0.178 / 0.152 in H2O in H2O0.178 / 0.152
Lowest friction rate in/100ft0.077in/100ft0.077
Actual air flow cfm800cfm800
Total effective length (TEL) ft429
Supply Branch Detail Table
Design Htg Clg Design Diam H x W Duct Actual Ftg.Eqv
Name (Btuh) (cfm) (cfm) FR (in) (in) Matl Ln (ft) Ln (ft) Trunk
st5190.021.3VlFx0x04.00.08416301481hBath 2
st4125.029.5VlFx0x07.00.1151131145733hBedroom 2
st5190.029.5VlFx0x05.00.08162753780hBedroom 3
st6185.033.5VlFx0x04.00.08232502507hDen
st7180.044.0VlFx0x06.00.08025422095hDining
st10175.054.5VlFx0x06.00.07882491633cKitchen
st10175.056.5VlFx0x06.00.07782491633cKitchen-A
st11150.054.3VlFx0x07.00.087114932264cLiving Room
st11150.053.2VlFx0x07.00.088114932264cLiving Room-A
st5190.022.0VlFx0x05.00.08430552734hMaster Bath
st2135.031.7VlFx0x05.00.10766763787hMaster Bedroom
st2135.032.3VlFx0x05.00.10766763787hMaster Bedroom-A
Supply Trunk Detail Table
Trunk Htg Clg Design Veloc Diam H x W Duct
Name Type (cfm) (cfm) FR (fpm) (in) (in) Material Trunk
st10 Peak AVF 97 164 0.077 470 8.0 0x0 ShtMetl st7
st7 Peak AVF 325 417 0.077 764 10.0 0x0 ShtMetl st6
st6 Peak AVF 375 449 0.077 572 12.0 0x0 ShtMetl st5
st5 Peak AVF 534 556 0.077 708 12.0 0x0 ShtMetl st1
st2 Peak AVF 151 131 0.107 566 7.0 0x0 ShtMetl st4
st4 Peak AVF 266 244 0.107 761 8.0 0x0 ShtMetl st1
st11 Peak AVF 186 227 0.087 850 7.0 0x0 ShtMetl st7
st1 Peak AVF 800 800 0.077 453 18.0 0x0 ShtMetl
22. 2014-Mar-18 18:55:54
Right-Suite® Universal 2013 13.0.09 RSU13868 Page 2
...e J, S and D report for websiteRight-Sized.rup Calc = MJ8 Front Door faces: S
Return Branch Detail Table
Grill Htg Clg TEL Design Veloc Diam H x W Stud/Joist Duct
Name Size (in) (cfm) (cfm) (ft) FR (fpm) (in) (in) Opening (in) Matl Trunk
rb2 20x 37511 449 197.0 0.077 572 12.0 x0 0 ShMt rt3
rb5 10x 20610 161 130.5 0.116 590 8.0 x0 0 ShMt rt1
rb3 10x 14410 128 126.5 0.120 539 7.0 x0 0 ShMt rt4
rb4 6x 7510 62 185.5 0.082 384 6.0 x0 0 ShMt rt3
Return Trunk Detail Table
Trunk Htg Clg Design Veloc Diam H x W Duct
Name Type (cfm) (cfm) FR (fpm) (in) (in) Material Trunk
rt3 Peak AVF 450 511 0.077 650 12.0 0x0 ShtMetl rt2
rt1 Peak AVF 800 800 0.077 573 16.0 0x0 ShtMetl
rt2 Peak AVF 594 639 0.077 598 14.0 0x0 ShtMetl rt1
rt4 Peak AVF 144 128 0.120 413 8.0 0x0 ShtMetl rt2
23. Job #: SEG 0314-077W
Performed by Tracy Savoy for:
Right-Sized Residence
ACCA Manual J Street
Oak Park, IL 60301
Savoy Engineering Group
Phone: (801) 949-5337
www.load-calculations.com
Scale: 1 : 81
Page 1
Right-Suite® Universal 2013
13.0.09 RSU13868
2014-Mar-18 18:57:36
...port for websiteRight-Sized.rup
N
Main Level
Master Bedroom
Master Bath
Master Wic Den
Dining Kitchen
Living Room
CL 2
Bedroom 2
Hall
Bath 2
Bedroom 3
10 x 4
76 cfm
8 x 4
55 cfm
8 x 4
50 cfm
8 x 4
42 cfm
10 x 4
82 cfm
18 "
8 " 12 "
7 "
8 "
5 "
4 " 6 " 6 "
6 "
12 "
8 x 8
144 cfm
8 x 6
75 cfm
10 x 10
206 cfm
7 "
8 "
16 "
5 "
4 x 10
82 cfm
10 x 4
114 cfm
7 "
10 x 4
114 cfm
7 "
10 x 4
75 cfm
5 "
8 x 4
30 cfm
4 "
10 x 4
114 cfm
7 "
12 x 18
449 cfm
6 "
12 "
10 "
10 x 4
76 cfm
5 "
8 "
7 "
14 "
12 "
8 "