Patent Grant
10563925
The present disclosure relates to a cooling assembly, and more particularly to the cooling assembly for a service vehicle.
Service vehicles, for example gas or oil fracturing vehicles, have many components such as an engine, a transmission system, a hydraulic system, a fracturing pump, among others, that are present on the service vehicle, and that may heat up during operation. These components require cooling by means of heat exchange with suitable radiators or other coolers based on the type of the components.
A box type cooling package having multiple coolers present on each of the four side faces of the cooling package may be utilized to cool the heated components. A fan is mounted on a top face of the cooling package for cooling fluids running through the coolers by drawing cool ambient air from around the cooling package. Based on the design, these cooling packages may draw air from all four side faces of the cooling package.
However, some components of the service vehicle that are positioned proximate to the cooling package, for example an engine of the service vehicle that may be hot can cause the air surrounding that engine to heat up. Thus, hot air may be drawn into the cooling package from the side face proximate to the engine. This may affect an overall cooling performance of the system. Further, the placement of the coolers on each of the four side faces of the cooling package may lead to a bulky design requiring considerable space. Some service vehicles may have limited space for the installation of the cooling package, making it challenging to accommodate the cooling package.
United States Published Application Number 2003/057005 describes an engine enclosure for use on a vehicle having a cooling system for a vertical shaft type engine with a cooling air intake fan disposed above the engine. The engine enclosure comprises an upper hood for covering the engine from above, the upper hood having an upper surface and right and left side surfaces extending downward from the upper surface, a lower hood for covering lateral areas of the engine, and a cooling air intake opening formed in a position above a lower end of at least one of the right and left side surfaces of the upper hood for taking in ambient air. A partition wall member is disposed between the cooling air intake opening and the cooling air intake fan for restricting mixing of ambient air drawn by the fan and heat generating from the engine.
In one aspect of the present disclosure, a cooling assembly for a service vehicle is provided. The cooling assembly includes a frame having a bottom face, a top face, and four side faces, all arranged to define an internal cavity. The bottom face is configured to be mounted on the service vehicle. The top face is opposite the bottom face and is configured to be fitted with a fan. Three of the four side faces are each configured to be fitted with at least one cooler. A remaining one of the four side faces is adjacent to and facing an engine of the service vehicle. The remaining face has a barrier element provided thereon. The barrier element is configured to restrict air from being drawn therethrough.
In another aspect of the present disclosure, a service vehicle is provided. The service vehicle includes a mainframe, an engine supported on the mainframe, and a cooling assembly. The cooling assembly includes a frame having a bottom face, a top face, and four side faces, all arranged to define an internal cavity. The bottom face is configured to be mounted on the service vehicle. The top face is opposite the bottom face and is configured to be fitted with a fan. Three of the four side faces are each configured to be fitted with at least one cooler. A remaining one of the four side faces is adjacent to and facing an engine of the service vehicle. The remaining face has a barrier element provided thereon. The barrier element is configured to restrict air from being drawn therethrough.
In yet another aspect of the present disclosure, a method for cooling of components of a service vehicle is provided. The method includes aligning a frame having four side faces, a bottom face, and a top face on a mainframe of the service vehicle. The method includes attaching the bottom face of the frame to the mainframe. The method includes fitting a fan on the top face of the frame. The method includes fitting at least one cooler on three of the four side faces of the frame. The method includes providing a barrier element on a remaining one of the four side faces of the frame proximate to and facing an engine of the service vehicle to restrict drawing air therethrough. The method includes operating the fan for drawing an airflow from each of the three of the four side faces of the frame for cooling the at least one cooler.
Other features and aspects of this disclosure will be apparent from the following description and the accompanying drawings.
Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or the like parts. Also, corresponding or similar reference numbers will be used throughout the drawings to refer to the same or corresponding parts.
Referring to
To perform the fracturing operation, fracturing fluid may be pumped into a wellbore at high pressure. Inside the wellbore, the fracturing fluid is forced into a formation being produced. When the fracturing fluid enters the formation, the fracturing fluid fractures, or creates fissures, in the formation. Water, as well as other fluids, and some solid proppants, may then be pumped into the fissures to stimulate the release of oil and gas from the formation. In some cases, fracturing rock in the formation may require that the fracturing fluid be pumped into the wellbore at very high pressure. This pumping is typically performed by the relatively large diesel-powered fracturing pumps.
During operation, some of the components of the service vehicle 100 may get heated up, requiring the components to be cooled. For example, the engine 104, the transmission system, the hydraulic system, the fracturing pump, and so on may need to be cooled. The present disclosure relates to a cooling assembly 114 associated with the service vehicle 100. The cooling assembly 114 is a box type cooling system and will be explained in detail relating to
Referring to
The bottom face 214 of the frame 202 is mounted on the service vehicle 100. In some embodiments, one more support panels 220 may be provided on the bottom face 214 of the cooling assembly 114 for firmly connecting the cooling assembly 114 to the service vehicle 100. In one example, the cooling assembly 114 is mounted on the mainframe 202 of the service vehicle 100, proximate to the engine 104. A fan 222 is mounted on the top face 212. In some embodiments, the fan 222 is made of plastic, to reduce the weight of the fan 222. The fan 222 may also be connected to a motor, a fan shroud, and other components associated therewith.
Three of the four side faces, that is 204, 206, 208, hereinafter referred to as three side faces 204, 206, 208, may have multiple coolers 224 installed thereon. More particularly, each of the three side faces 204, 206, 208 may include one or more coolers 224. Further, the coolers 224 on each of the three side faces 204, 206, 208 may be of different types. For example, the coolers 224 may include any of a radiator, a fuel cooler, a hydraulic oil cooler, a power end lubrication cooler, and/or a charge air cooler. Additionally, or optionally, other coolers 224 for cooling of other components on the service vehicle 100 may also be accommodated on the frame 202. Lines, pipes, and other connections, for example charge air lines, coolant and/or oil lines, associated with the coolers 224 may be housed within the internal cavity 216 of the frame 202.
An exemplary arrangement includes providing radiators and a power end lubrication coolers on one of the three side faces 204; charge air coolers 224 on another of the three side faces 206; radiators, a fuel cooler, and a hydraulic oil cooler on yet another of the three side faces 208. It must be noted that the arrangement of the coolers 224 on the three side faces 204, 206, 208 of the frame 202 may vary based on a length, a breadth, and/or a height of the frame 202. The arrangement shown in the accompanying figures is exemplary and does not limit the scope of the present disclosure.
A barrier element 226 is provided on a remaining one of the four side faces, hereinafter referred to as the one side face 210, of the cooling assembly 114. The barrier element 226 is provided proximate to and facing the engine 104 of the service vehicle 100. The barrier element 226 may be made of sheet metal. In one example, the one side face 210 may include channels (not shown) provided on an inner perimeter 228 thereof for receiving the barrier element 226, such that the barrier element 226 is affixed in position using mechanical fasteners. The barrier element 226 is configured to restrict and block the drawing of air from areas proximate to the engine 104. The barrier element 226 also causes sealing of the one side face 210 from ambient air, preventing air from entering the internal cavity 216 of the frame 202 when the fan 222 is switched on. The barrier element 226 includes a number of ports 230 provided thereon for fluidic connection between the coolers 224 and the other components of the service vehicle 100, for example, the engine 104 and a hydraulic pump (not shown).
Additionally, the frame 202 may include other support structures, such as support arms, frames, panels, brackets and so on for firmly holding the components in place on the frame 202. A core guard 232 is connected to the three side faces 204, 206, 208 via mechanical fasteners, such as bolts.
During operation, the fan 222 is switched on in suction mode, causing an airflow to be drawn from each of the three side faces 204, 206, 208 of the frame 202, except for the one side face 210 which is located near the engine 104. The barrier element 226 on the one side face 210 prevents, restricts, and blocks the air from being drawn through the one side face 210 and the areas proximate to the engine 104. The operation of the fan 222 causes cooling of the coolers 224 by heat exchange therewith.
The frame 202 may be made of any suitable material, for example, metal. The design, construction, shape, and/or dimensions of the frame 202 may vary based on the requirements of the system. The arrangement of the coolers 224 on the three side faces 204, 206, 208 of the frame 202 may also vary based on the requirements of the system.
The present disclosure provides the cooling assembly 114 for cooling of the components of the service vehicle 100.
The present cooling assembly 114 provides an effective solution for cooling the coolers 224 associated with the components of the service vehicle 100. The cooling assembly 114 has a box type cooling package design. When the fan 222 is operated in suction mode, the airflow is drawn from each of the three side faces 204, 206, 208 of the cooling assembly 114 having the coolers 224 installed thereon. The barrier element 226 mounted on the one side face 210 proximate to the engine 104 prevents the air from being drawn through the said side 210.
By preventing drawing of the air from the one side face 210 that faces the engine 104, an overall cooling performance of the system may be improved since the barrier element 226 blocks the heated air surrounding the engine 104 from entering the internal cavity 216 of the frame 202 when the fan 222 is operated in suction mode. Further, closing or blocking the one side face 210 by the barrier element 226 may assist in redistributing package restriction in such a way that the airflows with relatively higher velocity may be drawn through each of the three side faces 204, 206, 208 having the coolers 224 mounted thereon, further enhancing the cooling performance of the system.
The cooling assembly 114 offers a robust and compact solution having the coolers 224 mounted on each of the three side faces 204, 206, 208 of the cooling assembly 114, allowing the cooling assembly 114 to be installed in environments having space constraints. Further, the cooling assembly 114 may be relatively light weight and may be easily retrofitted onto existing machines. In some situations, for example in case of inspection or servicing, the barrier element 226 may be removed to access the internal cavity 216 of the frame 202, without having to go underneath the service vehicle 100.
Although the cooling assembly 114 has been described in connection with the service vehicle 100, the cooling assembly 114 may also be used in generator sets and other electric power applications.
While aspects of the present disclosure have been particularly shown and described with reference to the embodiments above, it will be understood by those skilled in the art that various additional embodiments may be contemplated by the modification of the disclosed machines, systems and methods without departing from the spirit and scope of what is disclosed. Such embodiments should be understood to fall within the scope of the present disclosure as determined based upon the claims and any equivalents thereof.
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