Patent application number | Description | Published |
20120080112 | Device for causing turbulent flow in a tank assembly - Disclosed is a device for causing turbulent flow in a tank assembly that has an internal fluid cell and a fitting for allowing fluid to enter and exit the fluid cell from the exterior of the tank assembly. The device includes a main body portion and first and second retaining arms. The first and second retaining arms extend from the main body portion of the device and are adapted and configured for supporting the device substantially within the fitting of the tank assembly. A plurality of curved vane elements extend from the main body portion which cause turbulent flow in the fluid cell of the tank assembly by redirecting fluid entering the tank assembly axially through the fitting in a non-axial direction into the fluid cell. | 04-05-2012 |
20120080438 | Devices and methods for causing turbulent flow in a tank assembly - Disclosed is a device for causing turbulent flow in a tank assembly that includes, inter alia, a base portion and a vane element that extends in an axial direction from the base portion. The vane element has a curved surface formed at a distal end thereof which is adapted and configured to redirect fluid traversing the device axially in a non-axial direction. Still further, a plurality of shoulder elements extend radially outward from the axis of the vane element and are adapted and configured for limiting that axial insertion of the device into a fitting associated with the tank assembly. In an embodiment of the present invention, the vane element includes lateral edges which are adapted and configured for press-fit engagement with an inside diameter of the fitting associate with the tank assembly. | 04-05-2012 |
20140157713 | VACUUM INSULATION PANEL ASSEMBLY - A vacuum insulation panel assembly having upper, lower, and first and second side vacuum insulation panels. The upper vacuum insulation panel has an aperture formed therethrough and an edge forming an overlap joint. The lower vacuum insulation panel also has an aperture formed therethrough and an edge forming an overlap joint. The first and second side vacuum insulation panels have an arcuate, half-cylindrical shape with a top edge forming an overlap joint configured to engage the overlap joint of the upper vacuum insulation panel, a bottom edge forming an overlap joint configured to engage the overlap joint of the lower vacuum insulation panel, and first and second side edges forming overlap joints configured to engage the overlap joints of the first and second side edges of the other side vacuum insulation panel. | 06-12-2014 |
20140158573 | AIR CELL INDICATOR - A fluid tank has a housing that has an upper end wall, a side wall, and a lower end wall that together define a cavity. A flexible diaphragm is connected to the side wall within the cavity and separates the cavity into an upper portion, which is sealed to contain a pressurized gas, and a lower portion, which is sealed to contain a pressurized fluid. An indicator is positioned in the upper wall of the housing and has an indicator arm and a visual indicator. The indicator arm is not visible and the visual indicator is visible with the indicator in a first position and the indicator arm is visible and the visual indicator is not visible with the indicator in a second position. | 06-12-2014 |
20140231439 | PLASTIC STAND AND METHOD OF ATTACHMENT TO A PRESSURE VESSEL - A stand for supporting a pressure vessel includes a support body having an upper wall and a sidewall extending downwardly from the upper wall. A locking aperture is defined in the upper wall to permit passage of pressure vessel components therethrough. A plurality of locking latches is disposed along an inner dimension of the locking aperture. The locking latches are configured and adapted to couple with a pressure vessel retaining ring passing through the locking aperture. | 08-21-2014 |
20150338011 | PRESSURE ABSORBER FOR A FLUID SYSTEM AND METHOD OF USE - Disclosed is an absorber system for absorbing pressure shocks and fluid volume shocks in a fluid system. In particular, the absorber system includes a housing with a joint for insertion within a fluid system, wherein the housing interior is in fluid communication with fluid in the fluid system. As such, when a pressure and/or fluid volume shock is developed within the fluid system, fluid is forced into the housing via the joint. A membrane is disposed within the housing in such a way that the fluid impacts the membrane which, in response, flexes to absorb and control the pressure and/or fluid volume shock within the fluid system. The absorber system, thus, controls pressure and/or fluid volume shock within a system and can prevent water hammer and other problems which can result from the development of pressure and/or fluid volume shock. | 11-26-2015 |
20150338012 | MULTI-LAYERED GAS-FILLED BLADDER FOR ACCOMMODATING CHANGES IN FLUID CHARACTERISTICS WITHIN A FLUID DELIVERY SYSTEM - An absorber for use in a fluid delivery system is disclosed which includes a housing defining an interior chamber, a connective fitting extending from the housing in fluid communication with the interior chamber for connecting the housing to the fluid delivery system, and at least one gas-filled bladder or cell disposed within the interior chamber of the housing to accommodate changes in fluid characteristics, such as, for example, pressure and volume, within the fluid delivery system, the gas-filled bladder or cell having a predetermined pre-charge pressure and a multi-layered flexible polymeric shell including a plurality of successive relatively thin polymeric shell layers to inhibit the formation of leak paths through the shell in the event that a single shell layer fails. | 11-26-2015 |
20150345802 | MOISTURE DETECTING AIR CAP INDICATOR FOR EXPANSION TANK FAILURE - Disclosed is an expansion tank having an internal cavity separated by a flexible diaphragm to form an upper pressurized gas portion and a lower pressurized fluid portion, and an indicator positioned at an upper part of the expansion tank in communication with the contents of the upper pressurized gas portion. The indicator is configured so as to display a first color if the operating conditions are normal in the pressurized gas portion, and a second color if the amount of moisture detected in the pressurized gas portion greater than or equal to a predetermined amount. Further disclosed is a method for detecting whether there is an excessive amount of moisture in a pressurized gas portion of an expansion tank by allowing pressurized gas from the pressurized gas portion to come into contact with the indicator, and viewing the color displayed by the indicator. As such, the tank can be simply visually inspected to determine whether there is a potential failure in the tank. | 12-03-2015 |