Heat Transfer Enhancement by Using Dimple Surface

Nowadays, to improve or to increase efficiency of heat transfer medium to another task is very difficult to find new method by using geometrical changes and some using the some external sources affected on heat transformation dimple surfaces in which the dimple is nothing but “hole” like or depression like structure in which air circulation is created and to help heat transfer more effectively, we create some shapes of dimple; and to this various shapes we compare with flat plate then we find some changes in our data. We can use various methods to identify which shape is more effective. Keyword: Dimple surfaces, layout and geometry, various shapes and arrangements


INTRODUCTION
The challenging task is to produce more effective and efficient heat transfer devices i.e. heat exchanger, to find the methods, which gives more information about the traditional method and to increase the heat transfer rate. To study heat transfer method industry and to increase the heat related factor such as heat transfer equipment and heat exchangers. To challenge some find new shapes and low cost and less material consumption which can be mainly considered. These visions are considered in our project.
Our project mainly depends on dimple surface, in which some geometrical changes have been done to increase heat transfer rate. We can mainly consider heat enhancement method in which ma methods are studied; and they are: active method, passive method and combine method. @ IJTSRD | Available Online @ www.ijtsrd.com | Volume -2 | Issue -3 | Mar-Apr 2018 Nowadays, to improve or to increase efficiency of heat transfer medium to another task is very difficult find new method by using geometrical changes and some using the some external sources affected on heat transformation dimple surfaces in which the dimple is nothing but "hole" like or depression like structure in which air circulation is created and to p heat transfer more effectively, we create some shapes of dimple; and to this various shapes we compare with flat plate then we find some changes in our data. We can use various methods to identify layout and geometry, The challenging task is to produce more effective and efficient heat transfer devices i.e. heat exchanger, to find the methods, which gives more information nd to increase the heat transfer rate. To study heat transfer method industry and to increase the heat related factor such as heat transfer equipment and heat exchangers. To challenge some find new shapes and low cost and less material n be mainly considered. These Our project mainly depends on dimple surface, in which some geometrical changes have been done to increase heat transfer rate. We can mainly consider heat enhancement method in which mainly three methods are studied; and they are: active method, 1. In active method, some geometrical changes are made to increase the heat transfer rate. 2. In passive method, some external sources are used to that source which helps to increase heat transfer rate. 3. Combine method is a combination of active and passive method in which some geometrical changes and some external sources can be used and to increase the heat transfer rate.
In our project, we can use combine method plate is considered and modified the plate with some geometrical changes and compared with flat plate; and also external sources like blower which gives air flow to the dimple plate have been used. After some analytical study, we can find out the between the flat plate and the dimple plate calculation and then we conclude that which dimple surface is more effective to increase the heat transfer rate and then we identify that the method used in our project is right or wrong. Mainly, we us mediums to transfer the heat in our project, we can say cold air and heat is the second medium to heat transfer; then our project is like heat exchanger and we can calculate the air distribution and project identification to increase heat calculation is done on heat transfer basis and all geometries are considered like various shapes and depth to height ratios. After studying previous papers, we concluded that the height to depth ratio matters to increase heat transfer rate.
This upper Figure 1 is flow phenomenon which mainly focuses on increasing the air circulations in the dimple surface. Air is passing dimple some air is In active method, some geometrical changes are made to increase the heat transfer rate. In passive method, some external sources are used helps to increase heat Combine method is a combination of active and passive method in which some geometrical changes and some external sources can be used and to increase the heat transfer rate.
In our project, we can use combine method in which plate is considered and modified the plate with some compared with flat plate; and also external sources like blower which gives air flow to the dimple plate have been used. After some analytical study, we can find out the difference between the flat plate and the dimple plate calculation and then we conclude that which dimple surface is more effective to increase the heat transfer rate and then we identify that the method used in our project is right or wrong. Mainly, we used two different mediums to transfer the heat in our project, we can say cold air and heat is the second medium to heat transfer; then our project is like heat exchanger and we can calculate the air distribution and project identification to increase heat transfer rate. Now calculation is done on heat transfer basis and all geometries are considered like various shapes and depth to height ratios. After studying previous papers, we concluded that the height to depth ratio matters to 1 is flow phenomenon which mainly focuses on increasing the air circulations in the dimple surface. Air is passing dimple some air is International Journal of Trend in Scientific @ IJTSRD | Available Online @ www.ijtsrd.com passing in that dimple and air circulation is created due to this boundary layer get disturb and form in Marathi vortex is called as "BHOVRA". The air circulation formed inside the dimples results in reducing and disturbing the thermal boundary layer and to helps the transfer the heat under the layer of dimple surfaces.
Each dimple acts as a "Vortex Generator" which provides an intensive and stable heat and mass transfer between the dimpled surface and gaseous heating/cooling media, taking advantages of vortex heat transfer enhancement (VHTE), suppose air is passed to dimple (Figure 2).

Research Gap
 Most of the papers [1, 2, 3, 5, 7 and 8] are related to the dimple geometry and modification and its applications to their uses.  No paper is related to how to improve heat transfer rate by dimple and its various types.  Main objective of our paper is to improve heat transfer rate by using dimple surfaces.  In this paper, we focus to obtain maximum heat transfer rate.  We used various geometrical changes done by our side.

METHODOLOGY USED
 Study the different methods used in our project.  To study various shapes and geometries in our project.  To use advanced technology for heat enhancement. passing in that dimple and air circulation is created due to this boundary layer get disturb and vortex is form in Marathi vortex is called as "BHOVRA". The air circulation formed inside the dimples results in reducing and disturbing the thermal boundary layer and to helps the transfer the heat under the layer of "Vortex Generator" which provides an intensive and stable heat and mass transfer between the dimpled surface and gaseous heating/cooling media, taking advantages of vortex heat transfer enhancement (VHTE), suppose air is Most of the papers [1, 2, 3, 5, 7 and 8] are related to the dimple geometry and modification and its applications to their uses. No paper is related to how to improve heat transfer rate by dimple and its various types.
is to improve heat transfer rate by using dimple surfaces. In this paper, we focus to obtain maximum

MATERIAL USED AND GEOMETRY SELECTION
In our project, we selected the and this material is reliable to various and then we selected total four shapes to the plate of aluminium whose dimensions are 405 and the distance between the dimples is 15 to that parameter considered a designed in its own way.
Test plate is of aluminum sheet of thickness 6 and having dimensions as 405 dimples produced on the test plate are of 8 diameter and 3 mm depth. For rectangular pattern arrangement, total 7 rows are employed in the stream wise direction and 14 columns are in span direction. Test section coordinate system is employed for the study. Note that Y coordinate is normal to the test surface and X coordinate system is along flow d direction. The spacing in between center of two dimples in X and Y direction is of 11 highlight all of the above affiliation lines. Figure shows the test with dimple section.
We can use total "9" numbers of plates in which we selected four shapes those are triangular dimple, trapezoidal dimple plate, oval shape dimple plate, and square shape dimple plate. And all plates are arrange inline and staggered shapes and all dimple plates are compared to flat plate which is made by aluminum. In case of in-line arrangement, all the dimples are in straight way and normally the all dimples are in straight line; and in the staggered arrangement, the dimple arrangement is mainly in the zigzag way. Some papers identify the in arrangement as less effective than the staggered arrangement. Because of that we compared flat plate, in-line arrangement plate and staggered arrangement

MATERIAL USED AND GEOMETRY
In our project, we selected the aluminium material and this material is reliable to various dimple shapes and then we selected total four shapes to the plate of aluminium whose dimensions are 405 mm×195 mm and the distance between the dimples is 15 mm each, to that parameter considered and then dimple plate is Test plate is of aluminum sheet of thickness 6 mm and having dimensions as 405 mm×195 mm. The dimples produced on the test plate are of 8 mm mm depth. For rectangular pattern al 7 rows are employed in the stream wise direction and 14 columns are in span-wise direction. Test section coordinate system is employed for the study. Note that Y coordinate is normal to the test surface and X coordinate system is along flow d The spacing in between center of two dimples in X and Y direction is of 11 mm up to highlight all of the above affiliation lines. Figure 3 shows the test with dimple section.
We can use total "9" numbers of plates in which we selected four shapes those are triangular dimple, trapezoidal dimple plate, oval shape dimple plate, and square shape dimple plate. And all plates are arrange inline and staggered shapes and all dimple tes are compared to flat plate which is made by line arrangement, all the dimples are in straight way and normally the all dimples are in straight line; and in the staggered arrangement is mainly in the g way. Some papers identify the in-line arrangement as less effective than the staggered arrangement. Because of that we compared flat plate, line arrangement plate and staggered arrangement In general, we can use one important part which is known as flow strainer and this part is mainly used to transfer equal amount of air to each dimple and is called as flow straightener ( Figure 4); and this equipment equally distributes the , passing air in all dimples; the passing air equally distribute by flow staightener of; in case the base of flow straightener is made of wooden plate to minimize the costing purpose, this device is used for long term and is very effective to transfer the flow in straight way and the equally distribute all the air passing is in equally manner in insulating box in which heater pate and the dimple plate available.  Dimension of the flow straightener is 300 mm×250 mm and is bigger than our test section plate fitted with convergent and divergent section.

Layout of Project
In case of the layout, we have used various equipment namely, blower, pressure control valve, pressure gauge, flow straightener, pipe, dimple plates, test section which is insulated box, thermo couple, various temperature sensors, digital temperature indicator and U-Tube manometer ( Figure 5). Steady state value of the plate and air temperatures in the channel, at various locations for a given heat flux and mass flow rate of air, is used to determine the values of performance parameters. The volume flow rate of air is determined from the pressure drop across the orifice meter, using a following relation: the useful heat gain of the air is calculated as: The heat transfer coefficient for the test section is calculated by Newton's law of cooling which states that, 'the rate of convection heat transfer is proportional to the temperature difference between surfaces of test plate and fluid.