The subject matter described herein relates to fluidizable beds, a method of heat management applicable to such beds, and to a fluid management system applicable to fluidizable and nonfluidizable beds.
A typical fluidizable bed includes a receptacle and a porous diffuser board that divides the receptacle into a plenum and a fluidizable medium container above the plenum. A quantity of a fluidizable medium, such as tiny beads, occupies the fluidizable medium container. The quantity of fluidizable medium is sometimes referred to as a bead bath. A filter sheet overlies the bead bath. The bed also includes a blower and a fluid transfer and conditioning system (also referred to as a conditioning system or a fluid conditioning system) for conveying a fluidizing medium to the bead bath. The fluid conditioning system includes at least one heat transfer device such as one or more heaters to heat fluid flowing through the conditioning system, and one or more radiators to cool fluid flowing through the conditioning system. Typically the conditioning system includes both a heater and a radiator. A control system turns the heater and radiator on or off as necessary to control the temperature of fluid flowing through the system.
In operation a fluidizing medium such as ambient air is pressurized by the blower and propelled through the conditioning system. As the fluidizing medium flows through the conditioning system it is exposed to the heat transfer device or devices and then flows into the plenum, through pores in the diffuser board, through the bead bath and finally through pores in the the filter sheet and into the local environment. The flow of the fluidizing medium through the bead bath imparts fluid-like properties to the bead bath so that the fluidizable medium acts as a quasi-fluid. Such beds are used for burn victims or other patients who have skin disorders such as pressure ulcers or who are at high risk of developing skin disorders as a result of long term confinement in bed.
In order to promote comfort of the bed occupant a user can specify an operating temperature for the bead bath. A commonly specified operating temperature is about 93° F. (34° C.). If the temperature of the bead bath is significantly below the specified operating temperature, as would likely be the case if the bed had not been in operation for an extended time, the temperature deficit causes the control system to turn on the aforementioned heater to heat the fluidizing medium so that the fluidizing medium can quickly heat the bead bath to the specified operating temperature. The control system may also command the heater to operate if the ambient air is especially chilly. More frequently, however, the control system operates the radiator rather than the heater because the blower itself rejects a considerable amount of heat into the fluidizing medium. Unless the radiator is turned on, the fluidizing medium will heat the bead bath to a temperature higher than the specified operating temperature. For example a typical blower warms the ambient air flowing through the fluid conditioning system by about 30° F. If the ambient air is 70° F. (21° C.) the bead bath would operate at a steady state temperature of about 100° F., which is about 7° F. (4° C.) higher than the commonly specified bead bath operating temperature of 93° F. Even if the 100° F. bead bath temperature is satisfactory for the bed occupant, heat transferred from the bead bath to the ambient air will make the temperature of the local environment uncomfortably warm for caregivers and/or increase the heat load imposed on any air conditioning system used to keep the local environment cool. If the 100° bead bath temperature is unsatisfactorally warm for the bed occupant, operation of the radiator will maintain the bead bath at a more suitable temperature such as 93° F. However the radiator will reject the heat removed from the fluidizing medium into the local environment. As a result the local environment will be uncomfortably warm, just as if the heat were rejected to the local environment from the bead bath.
Accordingly, it is desirable to establish simple, cost effective methods and systems for withdrawing heat from a fluid medium supplied to a bed without rejecting that heat to the local environment. Such systems and methods may be particularly applicable when applied to the fluidizing medium used in connection with a fluidizable bed.
A fluid management system for an occupant support comprises an impeller module which discharges fluid to a fluid destination, a motor module, and a coolant flowpath configured to service the motor module and to exhaust coolant to a coolant destination that differs from the fluid destination.
A fluidizable bed comprises an impeller module including an impeller, a fluidizable medium, a fluid conditioning system downstream of the impeller module. The fluid conditioning system is a fluid destination for fluid discharged from the impeller module and is also configured to convey the discharged fluid to the fluidizable medium. The bed also includes a motor module having a motor for driving the impeller. A coolant flowpath services the motor module and exhausts coolant to a coolant destination which differs from the fluid destination.
A method of heat management for a fluidizable bed having a fluidizable medium, an air mover and a motor for powering the air mover comprises directing a stream of fluidizing medium to the fluidizable medium, urging a stream of coolant to flow past the motor, and proportioning the coolant stream downstream of the motor between a first coolant destination and a second coolant destination as a function of temperature of the fluidizable medium.
The foregoing and other features of the various embodiments of the bed, method of heat management and fluid management system described herein will become more apparent from the following detailed description and the accompanying drawings in which:
Referring to
Referring additionally to FIGS. 3 and 5A-5C the bed also includes a fluid management system 40. The fluid management system includes a blower assembly 42 which comprises an impeller module 44 and a motor module 46. The impeller module includes an impeller housing 52 having an exterior end wall 54 and a circumferentially extending wall 56. An impeller fluid intake 58 penetrates end wall 54 of the impeller housing. An impeller fluid discharge 62 penetrates circumferentially extending wall 56 of the impeller housing. The impeller housing encloses an air mover such as a rotatable impeller 64. The motor module includes a motor housing 72 having an exterior end wall 74 and a circumferentially extending wall 76. A motor coolant inlet 78 defined by a series of slots 80 penetrates end wall 74 of the motor housing. A motor coolant outlet 84 defined by an array of slots 86 penetrates the circumferentially extending wall of the motor housing. The motor housing encloses an electric motor 92 which is connected to and drives the impeller. The blower assembly also has an internal partition 94 (
In operation ambient air serves as the fluidizing medium. The impeller draws the ambient air from the local environment by way of intake 58, pressurizes it, and propels it through impeller fluid discharge 62 to a fluid destination. The fluid destination is the fluid conditioning system 100A which appropriately conditions (heats or cools) the fluidizing medium as already described and conveys it to the bead bath.
The fluid management system also includes a coolant flowpath 130 which extends from motor coolant inlet 78 to a coolant destination by way of motor coolant outlet 84. The coolant flowpath is configured to service (i.e. cool) the motor module, specifically the motor and electronic components residing in the motor module, and to exhaust the coolant to a coolant destination outside the fluid management system and that differs from fluid destination 100A. Examples of various coolant destinations are described hereinafter. Typically, the coolant is ambient air.
Various types of valves 176 and corresponding operational options are envisioned. In one example valve 176 is a two position nonmodulating valve which is positionable at a recirculating position for directing substantially all of the coolant expelled from outlet 84 to the vicinity of fluid intake 58 and at an exhaust position for directing substantially all of the expelled coolant to a coolant destination 168 other than the vicinity of the fluid intake. In another example the valve is a three position nonmodulating valve positionable at the recirulating and exhaust positions just described and also positionable at a closed position. When positioned at the closed position the valve blocks fluid flow through coolant flowpath 130. As a result the fluidizing medium will be subject to greater heat transfer across internal partition 94.
In another example valve 176 is a modulating valve which is positionable not only at the recirculating and exhaust positions described above but also at intermediate positions in which the valve directs a fraction f of the coolant to the vicinity of fluid intake 58 and a fraction 1.0-f to the other destination 168. In the case of f=1.0, operation of the modulating valve corresponds to the recirculating position of the nonmodulating valve. In the case of f=0, operation of the modulating valve corresponds to the exhaust position of the nonmodulating valve. In another variant the modulating valve can also be positionable at a closed position at which it blocks fluid flow through coolant flowpath 130.
In accordance with the foregoing, a method of heat management for a fluidizable bed 10 having a fluidizable medium 30, an air mover 64 and a motor 92 for powering the air mover, will now be described. The method comprises the steps of directing a stream 180 of fluidizing medium to the fluidizable medium 30, urging a stream 182 of coolant to flow past motor 92, and proportioning the coolant stream downstream of the motor between a first coolant destination and a second coolant destination as a function of temperature of the fluidizable medium. In one example the proportioning step comprises channeling substantially all of the coolant stream to the first destination (e.g. intake 58) and substantially none of the coolant stream to the second destination (e.g. coolant destination 168) or channeling substantially none of the coolant stream to the first destination and substantially all of the coolant stream to the second destination. The proportioning step may also include an alternative of channeling substantially none of the coolant stream to either destination. In another example the proportioning step comprises channeling a fraction f of the coolant stream to the first destination and a fraction 1-f to the second destination. This fractionalized proportioning may also include an alternative of channeling substantially none of the coolant stream to either destination.
The fluid management system described herein is particularly applicable to fluidizable beds. However it may also be beneficial when used in connection with nonfluidizable beds, such as those that use pressurized air to inflate one or more supportive air bladders or in connection with toppers that use a stream of compressed air to keep an occupant cool and dry.
Although this disclosure refers to specific embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the subject matter set forth in the accompanying claims.
Number | Date | Country | |
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61678284 | Aug 2012 | US |