| GAYMAR INDUSTRIES, INC. Patent applications |
| Patent application number | Title | Published |
|---|
| 20120060295 | DECREASED SHEAR GELATINOUS CUSHION - A gelatinous elastomeric cushion having decreased shear forces applied to the patient by altering the gelatinous elastomeric configuration in certain areas. For example, the decreased gelatinous elastomeric material does not have secondary walls align with each other. Alternatively, the cushion has different gelatinous configurations in different sections of the cushion to intentionally elongate the walls to decrease the shear pressure applied to the patient. | 03-15-2012 |
| 20110030144 | CUSHION BLADDER WITH MIDDLE LAYER HAVING GAPS AND VARIOUS POSITIONED INTERIOR WELDS - A cushioning device has a first material and an opposing second material that are sealed together at the peripheral edges to form a first (right) side, a first (head) end, a second (left) side, and a second (foot) end. Positioned between the first material and the second material is a middle material. The middle material has a top side, a bottom side, a first gap between the first side and the middle material and a second gap between the second side and the middle material. In addition, the first material is sealed to the middle material's top side at a first set of locations to form a first set of interior welds. The second surface is sealed to the middle material's bottom surface at a second set of locations to form a second set of interior welds. The first set of interior welds on the middle material's top surface and the second set of interior welds on the middle material's bottom surface are not superimposed on each other or overlap each other. | 02-10-2011 |
| 20110010865 | MULTI-WALLED GELASTIC MATTRESS SYSTEM - The present invention is directed to a gelastic cushion. The gelastic cushion is made from a conventional gelastic composition. The gelastic cushion has a structure having a first wall that defines an opening area and buckles when a force is applied to the first wall. When the first wall buckles a predetermined amount, a second wall, interconnected to the first wall, also buckles. The second wall decreases the chance that the first wall bottoms out. Bottoming out increases the pressure on the patient (a.k.a., the force) overlying the gelastic cushion. That increased pressure is undesirable. | 01-20-2011 |
| 20100218317 | MULTI-WALLED GELASTIC MATERIAL - The present invention is directed to a gelastic cushion. The gelastic cushion is made from a conventional gelastic composition. The gelastic cushion has a structure having a first wall that defines an opening area and buckles when a force is applied to the first wall. When the first wall buckles a predetermined amount, a second wall, interconnected to the first wall, also buckles. The second wall decreases the chance that the first wall bottoms out. Bottoming out increases the pressure on the patient (a.k.a., the force) overlying the gelastic cushion. That increased pressure is undesirable. | 09-02-2010 |
| 20100207294 | MULTI-WALLED GELASTIC MATERIAL - The present invention is directed to a gelastic cushion. The gelastic cushion is made from a conventional gelastic composition. The gelastic cushion has a structure having a first wall that defines an opening area and buckles when a force is applied to the first wall. When the first wall buckles a predetermined amount, a second wall, interconnected to the first wall, also buckles. The second wall decreases the chance that the first wall bottoms out. Bottoming out increases the pressure on the patient (a.k.a., the force) overlying the gelastic cushion. That increased pressure is undesirable. | 08-19-2010 |
| 20100199437 | MULTI-WALLED GELASTIC MATERIAL - The present invention is directed to a gelastic cushion. The gelastic cushion is made from a conventional gelastic composition. The gelastic cushion has a structure having a first wall that defines an opening area and buckles when a force is applied to the first wall. When the first wall buckles a predetermined amount, a second wall, interconnected to the first wall, also buckles. The second wall decreases the chance that the first wall bottoms out. Bottoming out increases the pressure on the patient (a.k.a., the force) overlying the gelastic cushion. That increased pressure is undesirable. | 08-12-2010 |
| 20100106230 | Negative Pressure, Thermal Energy Transfer Device That Also Provides Positive Pressure to the Patient - A negative pressure, thermal energy device has an enclosure that receives a patient's body part. The body part is positioned in the enclosure and contacts a thermal energy contacting surface. The thermal energy contacting surface transfers its thermal energy to the body part. While in the enclosure, the body part is also exposed to a negative pressure to cause vasodilation. The combination of the vasodilation and the thermal energy transfer alter the patient's body core temperature. To ensure the body part remains in contact with the thermal contacting surface, the enclosure has a portion thereof that moves when negative pressure is in the enclosure. When the negative pressure is applied, the deforming enclosure material is pulled toward the body part to provide a positive pressure on the body part that ensures the body part effectively contacts the thermal energy contacting surface. | 04-29-2010 |
| 20100071137 | RESILIENT MATERIAL/AIR BLADDER SYSTEM - A fluid bladder system has a conventional fluid bladder and a resilient member in the fluid bladder. The resilient member is of a size that it allows the fluid in the fluid bladder to be the principal support applied to the patient. The resilient member only applies a force to the patient only after the patient displaces the fluid in the fluid bladder so the resilient structure is the only entity that inhibits the patient from bottoming out. | 03-25-2010 |
| 20090246449 | GELASTIC MATERIAL HAVING VARIABLE OR SAME HARDNESS AND BALANCED, INDEPENDENT BUCKLING IN A MATTRESS SYSTEM - A cushioning element has a first gelastic cushion element made from a flexible, resilient, gel cushioning media having shape memory. The first gelastic cushion element has a first hub section, and a first spoke and a second spoke. Each spoke has a proximal end that extends from the first hub section. Each distal end and the spoke area between the distal end and the proximal end does not interconnect to the other spoke, and/or a second gelastic cushion element having a second hub section and corresponding spokes. Each distal end is positioned near and/or contacts the second gelastic cushion element. At least one of the first hub section, the first spoke and the second spoke is capable of buckling beneath a protuberance that is located on the object. | 10-01-2009 |
| 20090143844 | HOSE MANAGEMENT FOR CONVECTIVE DEVICES - The present invention is directed to a convective thermal unit. The convective thermal unit has the conventional blower that directs ambient air to a heating element, the heating element heats the air and the heated air is directed into a conduit. The conduit directs the heated air into a receiving unit like a blanket positioned over a patient. A difference between the prior art and the present invention is the incorporation of a shape memory polymer and/or alloy material into the conduit to ensure the conduit does not contact the ground when the convective thermal unit is not being used or not providing the desired thermal energy. | 06-04-2009 |
| 20090112298 | HIGH EFFICIENCY THERMAL ENERGY TRANSFER PAD - A thermal energy transfer pad is disclosed. The thermal energy transfer pad has a first flexible, thermal energy transfer sheet and a second flexible, thermal energy transfer sheet. The first flexible, thermal energy transfer sheet (a) is made of a first fluid impervious material, (b) has a perimeter measurement of A prior to manufacturing and (c) has a first thermal energy transfer thickness. The first flexible, thermal energy transfer sheet is molded to form fluid path troughs defined by interior protuberances and the first sheet's perimeter edge. That molding alters the first flexible, thermal energy transfer sheet's perimeter measurement to B, which is less than A. The second thermal energy transfer sheet (a) is made of a second fluid impervious material, (b) has a perimeter measurement of B and (c) has a second thermal energy transfer thickness. The second thermal energy transfer sheet is sealed to the first thermal energy transfer sheet along the first sheet's perimeter and at the first sheet's interior protuberances. That sealing creates a tortuous fluid path in the fluid path troughs The resulting pad has a significantly (1) decreased chance of the fluid being occluded in the fluid path and (2) increased thermal energy transfer rate to the patient. | 04-30-2009 |
| 20090106906 | SELF-CONTAINED GATCHING, ROTATING AND ADJUSTABLE FOOT SECTION MATTRESS - A self-contained gatching mattress having a gatching mattress sleep deck, a first air bladder cushion, a second cushion material, a control box having an air pump system and a manifold, a conduit distribution unit, a sliding bridge, and a cushion material positioned above the sliding bridge and the control box. The sliding bridge forms a gap area for conduits to extend from the control box to the conduit distribution unit which decreases the chances of the conduits being kinked or altering the cushion's tissue interface pressure to patient's positioned on the cushion when the sleep deck is gatched and/or portions are retracted or extended. | 04-30-2009 |
| 20090106898 | ADAPTABLE MATTRESS CONVERSION - A mattress system has a cover, a crib, and a fluid bladder system. The crib surrounds the perimeter of the fluid bladder system and the cover overlies the top surface of the crib and fluid bladder system. The fluid bladder systems provide at least one conventional bladder therapy to a patient positioned on the mattress system. The fluid bladder system interconnects to the crib to not form a hammock effect so the crib functions as a restraint. The fluid bladder is also designed to bottom out to form an exterior cavity. A second cushion is inserted into the exterior cavity and positioned so the crib continues to function as a restraint. The second cushion provides a therapy to the patient that is different from the fluid bladder system. | 04-30-2009 |
| 20080281387 | Medical Device Clamp - A medical instrument device interconnection system decreases the vibrational effects on a hospital pole. The medical device is contained in a case and the case has a first clamping member, a first biasing apparatus, a second clamping member, a second biasing apparatus, and a pole receiving trench. Each clamping member has a preferred position, an attachment position and a maximum tension position. In the preferred position the respective biasing members position the respective clamping member's distal end as close to each other as possible which inhibits a conventional hospital pole from entering the pole receiving trench. To obtain the maximum tension position, the person positioning the medical instrument device on the hospital pole aligns the pole receiving trench with the hospital pole so the hospital pole contacts the clamping members' exterior surface in the preferred position. The person raises the device in relation to the pole which causes the clamping members to rotate and expose the pole receiving trench. Once the hospital pole enters the pole receiving trench the respective biasing apparatus on each clamping member has the respective clamping members revert toward the preferred position. The preferred position cannot be obtained because the hospital pole in the pole receiving trench inhibits the clamping members from reverting to that position. Instead the clamping members are in the attachment position after the medical instrument device is lowered a little in relation to the hospital pole to obtain the maximum force in the attachment position. Collectively the biasing apparatuses through the clamping members in the attachment position provide more force to the hospital pole than the weight of the medical instrument device. That way the medical instrument device remains attached to the hospital pole and due to the flexible biasing apparatuses the device's vibration is suppressed while attached to the hospital pole. | 11-13-2008 |
