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New catalog- Javaher: new product of Patineh Sazan Fars with high qualification
کورت و پوخت سه‌باره‌ت به‌ ڕووکه‌شی سیلیلۆزیی په‌تینه‌سازانی فارس:
پیشه‌سازیی و سه‌نعه‌تی بیناسازیی مۆدێڕن و نوێ له‌ جیهانی ئێستادا ده‌یه‌وێ به‌ شێوه‌یه‌کی به‌رفره‌ نه‌گه‌یه‌نه‌ره‌کان، بۆ ناو هه‌مه‌جۆره‌ بینایه‌کی نیشتنگه‌یی و بازرگانیی ده‌کار بێنێ. ئه‌م پرسه‌ که‌ سووک و که‌مکێشبوونی بیناکانی لێده‌که‌وێته‌وه‌،بۆ خۆ هۆکارێکی هه‌ره‌ گرینگه‌ له‌پێناو ده‌کارهێنانی وزه‌ به‌ باشترین شێوه‌ له‌ ناو شوێنه‌ گشتییه‌کاندا‌.
کۆمپانیای به‌رهه‌مهێنانی  "په‌تینه‌سازانی فارس" به‌ هه‌ستکردن به‌و گرینگه‌،له‌ ڕێی ناساندنی ڕووکه‌شی سیلیلۆزیی "ته‌ره‌نۆم"ه‌وه‌  هه‌وڵی داوه‌ له‌ به‌رزکردنه‌وه‌ی ئاستی ستانده‌ردی ده‌کارگرتنی باشتری وزه‌دا ده‌وری هه‌ره‌ کارا ببینێ. ڕووکه‌شی سیلیلۆزیی "ته‌ره‌نۆم" جگه‌ له‌وه‌ی نه‌گه‌یه‌نێکی هه‌ره‌باشی گه‌رما و سه‌رمایه‌، له‌به‌ر دارابوونی شه‌به‌نگێکی ڕه‌نگیی تۆخ، ده‌بێته‌ مایه‌ی دروستبوونی که‌ش و هه‌وایه‌کی ئاوێته‌ به‌ شادی،له‌بار و تژی به‌ هێوری و ئه‌هوه‌نی له‌ناو ماڵه‌کاندا. ئه‌م جۆره‌ ڕووکه‌شه‌ که‌ ڕاده‌ی گونجاویی و سازگاربوونی له‌گه‌ڵ ژینگه‌ له‌ ئاستێکی باڵادایه‌، له‌ کاتی جێ به‌جێکردندا ته‌نیا ئاوێته‌ی ئاو ده‌کرێ.واته‌ هیچ چه‌شنه‌ توێنه‌ری کیمیایی بۆ جێ به‌ جێکردنی ده‌کار نایه‌.
گرینگترین تایبه‌تمه‌ندییه‌کانی ڕووکه‌شی سیلیلۆزیی بریتین له‌ :

  • بۆ شۆردن ده‌شێ
  • بۆ نۆژه‌نکردنه‌وه‌ ده‌شێ
  • له‌سه‌ر هه‌موو شوێنێک تاقی و جێ به‌ جێ ده‌کرێ
  • به‌ هه‌مه‌ جۆره‌ شێواز و فۆرمێکی ئه‌ندازه‌یی ده‌توانی جێ به‌ جێی بکه‌یت
  • ژماره‌ی ڕه‌نگه‌کانی به‌رفره‌وانه‌‌‌
  • نه‌گه‌یه‌نه‌ری گه‌رما
  • نه‌گه‌یه‌نه‌ری سه‌رما
  • نه‌گه‌یه‌نه‌ری ده‌نگ
  • نه‌گه‌یه‌ن و دابڕی شێ
  • که‌مکردنه‌وه‌ی ڕاده‌یه‌کی فره‌ی وزه‌ی ده‌کارهاتوو
  • که‌مکردنه‌وه‌ی ڕه‌نگدانه‌وه‌ی تیشک
  • که‌مکردنه‌وه‌ی په‌رچ و ڕێفلێکسی ده‌نگ
  • خۆڕاگر له‌ به‌رامبه‌ر ئاگردا
  • خۆڕاگر له‌ هه‌مبه‌ر زه‌بروێکه‌وتن
  • قڵیش نه‌بردن
  • هه‌ڵگری تایبه‌تمه‌ندی ئه‌نتی ستاتیک(ته‌پ و تۆز و گه‌ردیله‌ی سووتاوی ناو هه‌وا به‌ خۆوه‌ ناگرێ)
  • خێرایی بان له‌ جێبه‌جێکردندا
  • نه‌بوونی بۆن و مادده‌ی هه‌ڵمه‌نی(خێرا به‌ هه‌ڵم بوون)
  • ته‌مه‌نی درێژی کاڵا
  • ده‌ست پێوه‌گرتنی ئابووری
ڕووکه‌شی سیلیلۆزی بۆ ئه‌م کارانه‌ ده‌کار دێت:
ڕووکه‌شی سیلیلۆزی ده‌توانی بۆ هه‌موو شوێنێک ده‌کار بێنی.
ئه‌م به‌رهه‌مه‌ زۆر وه‌به‌ر سه‌رنجی ئه‌وانه‌ی ده‌که‌وێ که‌ کاری بیناسازیی به‌ کۆمه‌ڵ  ده‌که‌ین یان به‌ واتایه‌کی ڕاست تر ئه‌وانه‌ی کۆمه‌ڵگا‌ی نیشتنگه‌یی دروست ده‌که‌ن که‌ به‌مه‌به‌ستی  ده‌س پێوه‌گرتنی ئابووری و کات به‌ فیڕۆنه‌دان پاش جێ به‌جێکردنی قۆناخی خاک و گه‌چکاری ،کاری دانانی ڕووکه‌شی سیلیلۆزی ئه‌نجام ده‌گرێ.
به‌واتایه‌کی تر قۆناخی گه‌چکاری که‌ دیاره‌ کات و وه‌ختێکی فره‌ ده‌بات و له‌هه‌مان حاڵدا خه‌رجی زۆریش هه‌ڵده‌گرێ،له‌ کۆڵ ده‌کاته‌وه‌. هه‌ر وه‌ک ئیشاره‌تی پێدرا،ڕووکه‌شی سیلیلۆزی بۆ هه‌موو شوێنێک وه‌ک گه‌ج،ڕه‌نگ،دار و هتد به‌ ڕه‌چاوی ڕێکارنامه‌که‌ی کارکردنی کۆمپانیای  په‌تینه‌سازانی فارس ده‌شێ و ئیشی پێده‌کرێ.
هه‌روه‌ها ئه‌م چه‌شنه‌ ڕووکه‌شه‌ بۆ کاری دیکۆرسازکردن له‌ شوێنی جۆربه‌جۆر ده‌کار دێت. واته‌ جگه‌ له‌وه‌ی هه‌ڵگری تایبه‌تمه‌ندی نه‌گه‌یه‌نه‌ربوونه‌،بۆ ڕازاندنه‌وه‌ و جوانترکردن له‌ جوانکاری و دیکۆراسیۆنی ناوه‌وه‌یش ده‌کار دێت و که‌ڵکی هه‌یه‌.

ئه‌م جۆره‌ ڕووکه‌شه‌ له‌به‌ر ده‌کارگرتنی شه‌به‌نگێکی ڕه‌نگیی تۆخ و  گونجاویی بۆ جێ به‌جێکردنی له‌ فۆرمی جۆربه‌جۆردا(وه‌ک شێواز و فۆرمه‌کانی ئه‌ندازه‌یی و فۆرمی سرووشتیی میناک گوڵ و دار و دره‌خت و ... )بۆ شوێنه‌کانی فێرکاریی وه‌ک باخچه‌ی ساوایان،خوێندنگه‌کان و زانستگه‌کان ده‌کار دێت  و وێڕای دروستکردنی که‌ش و هه‌وایه‌کی ئۆقره‌به‌خش،شوێنێکی هه‌ره‌ جوان و سه‌رنجڕاکێشیش چێ ده‌کات.
ئه‌م چه‌شنه‌ ڕووکه‌شه‌ هه‌روه‌ها بۆ ناو هۆڵه‌کانی میوانداریه‌تی،هۆڵی سینه‌ما و شوێنه‌گشتییه‌کانی قه‌ره‌باڵغی وه‌ک هۆڵی مێترۆ،گاراژ و ترمیناڵ و فڕگه‌کان ده‌کار دێت.
ئه‌م جۆره‌ مادده‌یه‌ له‌به‌ر ده‌کارگرتنی مادده‌ی سه‌ره‌تایی به‌ ته‌واوه‌تی سرووشتی و به‌بێ مادده‌ی پیسکه‌ری کیمیایی ده‌توانێ شوێنێکی ته‌واو پاقژ و ئارام و هێور له‌به‌ر ڕێفلێکسی نزمی ده‌نگ دروست بکات.


CELLULOSIC PATINA FINISH
INTERNAL FINISH AND INSULATION OF BUILDING



Introduction


The industry of the modern building construction is after the wide application of insulating materials for residential, commercial, and administrative structures.

With the above understanding, Tolidi Patina Sazan Pars Company, by introducing the Cellulosic Patina Finish has tried to take an effective step in raising the optimum energy consumption standard and arriving at a modern industry of building construction in our beloved country.

The Cellulosic Finish, which is highly compatible with the environment, needs only to be mixed with some water, therefore no chemical solvents are used for the application.  Additionally, due to varied compounds of color and pleasant effects, the finish creates a lively environment together with tranquility within the building.   

Besides, the finish has additional significant features, including, washable, repairable, antistatic (repelling dust and burned molecules in atmosphere), applicable on diversified surfaces, different design styles, unlimited varieties of colors, heat and cold insulating, soundproof, moisture proof, considerable saving in  energy consumption, lower light reflection, lower sound eco, no cracks, shock resistant, fire resistant, quick application, high longevity, no odor, and no volatile material.

Cellulosic finish is extensively used within the advanced industrialized nations, and it is certified by reputable competent authorities internationally, such as The German Biology Institution, Berlin Institute for Study and Testing of Materials, The Russian Institute for Health and Hygiene, Istanbul University Center for Material Test and Production Technology, also certification by German DIN standards.

Comparative Study of the Specifications of the Cellulosic Finish (Patina) with other Construction Materials



The cellulosic finish meets the objectives of a modern building construction via the view of three working factors:

   A. Expense
   B. Comfort and Safety
   C. Refining the Environment

Some of the major features of cellulosic finishes--that are clearly instrumental in controlling the above mentioned factors—are as follows:

   1. Heat insulating
   2. Sound proof
   3. Moisture proof
   4. Low weight
   5. Fire resistant
   6. Quick application
   7. Beauty and diversity in color
   8. Optimization in energy consumption

Each of the features assists us in arriving at the objectives in an ideal building construction by means of elevating the capability in controlling one or the three above factors, A, B, and C.

In this chapter, we compare the above features with that of similar materials, in order to attain reasonable physical quantities in the area of replacing the cellulosic finishes with similar materials.


1 – Thermo physical Characteristics (Heat Insulating)

This feature that resulted in the recognition of the cellulosic finishes as a heat insulating prioritizes the application of this material to similar ones by controlling the above three factors A, B, and C.

Table 1 – Thermo physical characteristics of insulations and common construction materials

ItemType of MaterialThermal Conductivity Coefficient (W/mk)
1Gypsum plaster0.22
2Mineral Wool0.046
3Asphalt0.062
4Brick0.72
5Cement Mortar0.72
6Cork0.039
7Cellulosic0.039

 According to the above table, the cellulosic finishes have a very low thermal conductivity coefficient.  Comparing the numerical amount of 0.22 (the thermal conductivity of gypsum) and .039 (the thermal conductivity of cellulosic finishes) it is indicative of exceptional difference between these two materials (please note that the cellulosic finishes are a replacement of gypsum plaster and paint together). 

Also comparing the numerical amount of 0.046 (the thermal conductivity of mineral wool) and o.039 (the thermal conductivity of cellulosic finishes) reveals that the insulating quality of this material is not only incomparable with gypsum, but also preferable to the common insulating materials in constructions.

This characteristic is helping us in the control of the two above A and C factors.  Naturally, the insulating power of the material will lower the energy consumption for heating and cooling in the buildings, and the reduction in energy consumption leads to lowering the cost of energy supply, reducing the size of the heating and cooling units (controlling the above factor A) , and finally lowering the rate of polluting the environment (controlling the above factor C).   

We have presented the extent of achieving the objective in quantitative form in “The Optimization of Energy Consumption” chapter.


2 – Sound Insulating

Once a building is sound proof, then an environment with more peace and comfort is created.  In this way the annoying noises are banned from entering the building, thus we reach the factor B of the above, that is an ideal construction work.

Table 2- Acoustic characteristics of insulators and current construction materials

ItemMaterial TypeThick mmTransmission Loss Coefficient
1Brick wall no gypsum plaster 140.533
2Brick wall with gypsum plaster 152.543
3Wood 518.5
4Porous gypsum board 7627.2
5Cellulosic finish 324

Referring to Table 2, we get once the gypsum thickness of 12.5 mm, we will have just 10 db of sound loss (discrepancy of items 1 and 2 in Table 2).  While, with a layer of cellulosic finish with 3 mm in thickness we will arrive at 24 db of sound loss.  Assuming that the rate of sound loss is in direct proportion with material thickness, with respect to the thickness and the sound loss coefficients in the above, we will have:

(24/10) X (12.5/3)= 10

That is, the cellulosic finishes are 10 times more efficient in sound insulating as compared with gypsum plaster.  Needs to add that the range of sensitivity of human ear to sound intensity is as follows.

Best suitable sound to human ear:10 – 30 db
Medium and fairly suitable:30 – 50 db
Loud and unsuitable:50 – 70 db
Annoying and deafening:70 – 90 db

Considering the small discrepancy between the standard and abnormal sound and the sound loss through a 3 mm layer of cellulosic finish, it seem quite interesting. As the above table and the explanation, if a loud and annoying sound (50 – 70 db) is produced outside a building, by applying just a 3 mm layer of cellulosic finish on the building walls the annoying sound can be reduced to best or medium one.

The range of an excellent sound 10 <  50  - 24 <  30
The range of a medium sound 30 < 70  - 24  <  50

This characteristic has extended the application of the cellulosic finishes to amphitheatres, conference halls, cinemas and else.


3 – Moisture Insulation

The moisture absorption power in cellulosic finishes is up to 17%, without losing the heat insulating and covering qualities, whereas, as compared with gypsum, this figure is only 10%.  Also the volume shrinkage against o.98% of moisture is exceptional and the actual shrinkage is only 2.2%.

Therefore, the cellulosic finishes are not prone to destruction due to moisture and the resulting shedding, so lowering the repair costs, (controlling the factor A above).  Besides, in case of use as interior finish, it will help the surrounding stay as pretty (controlling the factor B above).


4 – Weight

The following table is indicative of the density of cellulosic finishes, as compared with that of other construction materials.

Table 3 – The density of insulations and other common construction material

ItemType of MaterialDensity (volumetric mass) kg/m^3
1Gypsum plaster 1680
2Mineral wool 190
3Asphalt2115
4Brick1920
5Cement mortal1860
6Cork120
7Cellulosic finish45

As it is noted the cellulosic finishes possess the lowest density among other construction materials and for the application require minimum thickness (according Table 2) which leads to a lower weight on the building.  Such exceptional low weight same way requires less labor, transportation, and storage as compared with gypsum and paint, as well as other insulators leading to lower cost (controlling factor A above).  Also the lighter weight helps lowering the weight of the building concluding in smaller dimensions, lighter columns, and foundations that will decrease the cost (controlling factor A above) and all these will diminish the earthquake hazards (controlling factor B above).

Regardless of the implementing, developing and minor weight advantages of the material, if we wish to include the transportation costs in a rough comparison, we shall arrive at an interesting conclusion with an approximate example:

Supposing we wish to finish the surface of the walls of building with 350 sqm.  In case of using gypsum layer of 5 mm in thickness, the required volume of gypsum would be 1.75 cubic meter, that it would be equivalent to the volume of a Nissan car room.  But considering the high density of gypsum, to transport it a Nissan pick up would not be powerful enough, so a larger vehicle as a truck is needed to transport (1.75 X 1680 = 2940 kg) of load.  While, to finish the same surface of walls by using cellulosic finish with the same thickness, only (1.75 X 42 = 73 kg) of the material is needed, and the load is easily transportable in a Nissan pick up.  This preliminary comparison discloses the considerable transportation costs and economization in fuel consumption in the vast national level (controlling factors A and C above). 

 
5 – Fire Resistant

What may occur to one’s mind, by the appearance of cellulosic finishes, is its inflammability.  According to the international standard ASTM E119 there is a definition for inflammability namely “Flame Spread Coefficient”.  It is interesting that according to this standard the coefficient for cellulosic finish is the same for gypsum, as 15.  This quality is assisting us towards attaining the controlling factor B above.


6 – High speed Execution

Time is a factor, which is quite effective in rising or lowering the expenses.   The shorter the execution period the lower the construction work costs.  The costs relating to site mobilization, manpower, labor, storage, administrative, and else that are involved as side expenses during the execution can be lowered by shortening the execution period.  In addition, by shortening the execution period the timing of capital return will move up and in this way helps the cost controlling. 

In another rough comparison, for finishing a wall surface as much as 300 square meter (an apartment with 120 square meter area) a gypsum plaster craftsman and a help would be spending about 10 days; and a painter craftsman with a help would need 2 days for preparation and another 8 days to carry out the paint work.  Therefore, 20 days in total is needed to implement the gypsum and paint work of the apartment; whereas covering the same walls with cellulosic finish by a craftsman and a help would take no longer than 3 days.  This simple example reveals the economization of time by 85% that naturally helps us in controlling the factor A above.


7 – Beauty and Variety in color

With respect to the amazing influence by architecture in one’s spiritual health and moods, the significance of painting and decoration is disclosed.   

The color composition and the pretty look of the cellulosic finishes has encouraged us to use them, in particular within day nurseries, schools, hospitals, sport centers, work places, and administrative centers; and it is assisting us in attaining to factor B above.


8 – Optimization of Energy Consumption 

In development projects (in particular large or high rise buildings) one of the most effective factors in raising the executing costs are the air conditioning systems installation.  In addition, apart from the installation, the energy supply to enjoy a pleasant cool air in summer and a pleasant warm air in winter will burden a high cost to the users of the building. 

Additionally, the uncontrolled consumption of energy results in the wasting the national capitals at the same time causing intensive pollution of the environment.  Therefore, the lowering consumption of energy in a building will lead to controlling the factors A and C above.

We can show the lowering consumption of energy by using cellulosic finish in place of gypsum and paint, in a simple example:

Let’s assume an enclosure by 1 cubic meter in volume (1 x 1 x 1) made of brick.  In one time we cover the surface we gypsum by 5 mm in thickness, and the next time with cellulosic finish and same 5 mm thickness.  We like to learn, in each case, how much of cooling rate in W is required to maintain a constant temperature difference of ∂t = 10, between the interior and exterior space (∂t = T1 – T2 = 10) where we arrive at a criteria to compare the optimization of energy / fuel consumption.

Assumptions :

The heat is transferred by conduction. 
The temperature difference of interior and exterior space     ∂t = 10 degree
The thickness of brick wall     Rw = 0.2m
The thickness insulation (interior cover)     Ri =Rg = Rc = 0/005m           
Thermo physical characteristics of gypsum (Table 1)     Kg = 0.22 w/mk
Thermo physical characteristics of cellulosic insulation (Table 1)     Kc =0.039 w/mk
Brick wall thermo physical characteristics (Table 1)     Kw = 0.72 w/mk

Bearing in mind that the required thermal load is obtained from the formula

q = ∂t / { (Rw / Kw * A) + (Ri / Ki  * A) }

The example is applied for both cases as follows.

I – Using gypsum for interior cover:

q = ∂t / { (Rw / Kw *A) + (Rg / Kg *A) } =

qg = 10 / { (0.2 / (0.72 x 1 ) + ( 0.005/(0.22 x 1 )} = 33.3 w

to incorporate the six faces of the enclosure:

Q = 6 q = 6 x 33.3 = 200 w

Therefore, to maintain a 10 degree C temperature difference between the interior and exterior space, in the case that the enclosure is covered with gypsum, we will need a thermal energy equivalent to 200 watt.

II – Using cellulosic insulation covering the interior surfaces:

q = ∂t / { (Rw / Kw *A) + (Rc / Kc *A) } = qc = 10 / { (0.2 / (0.72 x 1 ) + ( 0.005/(0.039 x 1 )} = 24.63 w

to incorporate the six faces of the enclosure:

Q = 6q = 6 x 24.63 = 148 w

It is learned that to maintain the same temperature condition, we will need 148 w.

This simple example clarifies that by using cellulose insulation we will need 200 – 148 = 52 w less, that is 0.26% less energy or fuel.


The splendid result of 0.26% in optimization of less energy is not anything to be ignored.  The tremendous costs imposed on the nation and the state on account of uncontrolled consumption of energy and fuel is not covered to anybody.

The example is indicative that in the event of using cellulosic insulations, in place of gypsum and paint, the heating and cooling systems may be selected as much as 0.26% smaller in capacity, which means lowering the costs of the construction and the air conditioning systems.