Class / Patent application number | Description | Number of patent applications / Date published |
165085000 | AGITATOR OR IMPELLER MOTOR OPERATED BY EXCHANGE FLUID | 10 |
20110108238 | HIGH-EFFICIENCY ENHANCED BOILER - The invention provides high-efficiency heat transfer devices and apparatuses In one embodiment, the invention includes a vessel capable of containing the heat transfer medium, a conduit extending through a wall of the vessel, the conduit having a first surface for contacting the heat transfer medium and a second surface for contacting a fluid within the conduit, a helical member residing around and along a length of the first surface of the conduit capable of angularly directing a flow of the heat transfer medium along the first surface of the conduit; and a plurality of fins helically arranged adjacent the helical member, each fin extending through a wall of the conduit and being capable of directing at least a portion of the heat transfer medium to an area within a radius of the conduit. | 05-12-2011 |
20130000866 | Energy Efficient Cooling Tower System Utilizing Auxiliary Cooling Tower - A cooling tower system, including a principal cooling tower; an auxiliary cooling tower for receiving a portion of the warm water flow into the main tower; a central shaft mounted vertically in the auxiliary tower; a turbine mounted on a portion of the shaft; a cooling blade mounted on the upper end of the shaft; a water jetting system delivering warm water under pressure from the main cooling tower into the auxiliary cooling tower to impart rotation to the turbine blades for imparting rotation to the cooling blade; a quantity of high efficiency film fill in that portion of the tower below the turbine for receiving the water coming off of the turbine blades; air flow produced by rotation of the cooling blade upward through the fill in order to cool the water before it is returned to the main cooling tower. | 01-03-2013 |
20130180685 | Heat Exchange System for a Cavitation Chamber - A method and apparatus for regulating the temperature of the cavitation medium for a cavitation chamber is provided. A heat exchange fluid is pumped through a heat exchange conduit that passes through a portion of the cavitation chamber. An external heat exchanger, couples either directly or indirectly to the heat exchange conduit, regulates the temperature of the heat exchanger fluid which, in turn, regulates the temperature of cavitation medium within the cavitation chamber. The heat exchanger can be used to lower the temperature of the cavitation medium to a temperature less than the ambient temperature; to withdraw excess heat from the cavitation medium; or to heat the cavitation medium to the desired operating temperature. The heat exchanger can utilize heated heat exchange fluid, cooled heat exchange fluid, thermoelectric coolers, heat sinks, refrigeration systems or heaters. | 07-18-2013 |
20130255915 | SELF-POWERED HEAT EXCHANGER - A heat transferring apparatus may employ a heat exchanger with a fluid inlet and a fluid outlet and be coupled to a power exchange unit, which employs a driving fan fluid inlet, a series of inner fan blades to receive the fluid from the driving fan fluid inlet, and a rotable driving fan unit. The inner fan blades are attached to the rotable driving fan unit along with driving magnets. A rotatable driven fan unit has numerous outer fan blades and a series of imbedded driven magnets. The fluid drives the inner fan blades and flows into the heat exchanger. The outer fan blades force air through the heat exchanger and cools the fluid. A power transfer wall located between the inner magnets and the outer magnets transfers magnetic fields from the inner magnets to the outer magnets to impart rotation in the driven fan unit and outer fan blades. | 10-03-2013 |
20130327499 | EGR COOLER AND METHOD - A device and method for enhancing the flow of coolant through an EGR cooler, are described. The device includes a housing or tank having an interior space with a fluid inlet for receiving coolant and a fluid outlet for releasing coolant from the interior space. A series of angled baffles in a parallel arrangement are positioned within the interior of the housing from the fluid inlet to the fluid outlet. The baffles extend into a flow path of the coolant redirecting a portion of the flow path above and below the baffles as the coolant passes through the housing. A plurality of tubes or conduit are positioned adjacent the baffles, defining an exhaust gas flow pathway through the housing. | 12-12-2013 |
20140202659 | POULTRY CARCASS COOLING AND CONVEYING SYSTEM - In a hollow cylindrical housing which stores a coolant, a feeding device having a rotating shaft and spiral screw vanes fixedly installed on the periphery of the rotating shaft is provided. At least one first diffusion nozzle is provided in each pitch of the screw vanes on the inner wall of the housing. A pair of second diffusion nozzles are provided for every pitch of the screw vanes on the outer periphery of the rotating shaft respectively at different positions in the axial direction of the rotating shaft and at mutually opposite positions in the circumferential direction of the rotating shaft. The first diffusion nozzles are supplied with wash water through a high-temperature water piping provided on the upper outside of the housing, while the second diffusion nozzles are supplied with wash water through a channel formed in the interior of the rotating shaft. | 07-24-2014 |
20140262152 | Poultry Chiller with Multi-Blade Long-Pitch Auger - An auger-type poultry chiller having an auger with multiple long-pitch auger blades. The blades of the auger create pockets that spiral around the auger shaft and extend the length of the auger. While the product in the chiller is locked into a certain pocket, it is not locked into a certain spot lengthwise in the chiller. The product, therefore, is able to distribute evenly along the length of the chiller within its pocket even if there are gaps in loading time or if unloading stops momentarily. | 09-18-2014 |
20150047810 | Heat Exchanger with Inner Fluid to Actuate the External Fluid Pump - The present invention provides a heat exchanger with inner fluid to actuate the external fluid pump capable of driving one or more than one of fluid actuation devices through fluids passing through the heat exchanger having thermal-energy fluid pipe, without utilizing external mechanical rotational kinetic energy or power of electric motors; respectively driving external fluid pumping blade devices installed at lateral sides of the heat exchanger having thermal-energy fluid pipe with a direct or non-contact transmission means, so as to drive the external fluid to pass through the heat exchanger for increasing the heat exchange efficiency of the heat exchanger. | 02-19-2015 |
20150129170 | Three-Paddle Rocker Chiller - A rocker-type poultry chiller, including a tank for receiving poultry carcasses and holding chilled water, an axle mounted in the tank, a main paddle connected to the axle, and a side paddle connected to the axle. The oscillation of the main paddle and the side paddle urges the carcasses upwardly and laterally, which contributes to the cooling of the carcasses as a result of their thorough contact in the chilled water. The movement of the paddles also gently massages the carcasses by gently bumping them against the paddle blades and the wall of the tank. The repeated compression of the carcasses tends to tenderize the meat. The side paddles ensure more predictable and consistent contact between the paddles and all of the carcasses, which causes more agitation of the carcasses and more effective washing of the carcasses. | 05-14-2015 |
20150289526 | Poultry Chiller with Multi-Blade Long-Pitch Auger - An auger-type poultry chiller having an auger with multiple long-pitch auger blades. The blades of the auger create pockets that spiral around the auger shaft and extend the length of the auger. While the product in the chiller is locked into a certain pocket, it is not locked into a certain spot lengthwise in the chiller. The product, therefore, is able to distribute evenly along the length of the chiller within its pocket even if there are gaps in loading time or if unloading stops momentarily. | 10-15-2015 |