The present invention relates to a support member and patient lifting device for displacing persons between various positions and locations. More specifically, the present invention relates to an infection control lifting strap and system for lifting and positioning patients using a non-porous, sealed strap to provide improved infection control.
Patient lifting devices allow persons to be displaced between various positions and locations. The devices are typically used to lift and move patients that may not be otherwise moved without injury or substantial effort by either the patient or the caregiver. The patient needing intervention from a lifting device is usually overweight, dystrophied, unconscious, or injured.
A traditional patient lifting device uses manual labor to displace the patient. Manual patient lifting devices may use hydraulic pumps or other fluid- or air-powered pumps to assist the caregiver moving the patient. The pump is attached to a lever that the caregiver may raise and lower to displace the patient into various positions and locations. Depending on the strength and experience of the caregiver, as well as the type of pump used, this type of device may be difficult or even dangerous to use for both the patient and the caregiver. However, it is still readily available due to its lower cost.
More recent patient lifting devices are electrically operated. Electric patient lifting devices utilize a motor system to raise and lower the patient. Once the patient is secured to the device, the caregiver simply uses a button or switch to cause the motor to displace the patient. Electric patient lifting devices have become the preferred devices due to their ease of use and minimal human involvement, limiting the risk of misuse and accident, or injury to the patient and caregiver. Furthermore, electric patient lifting devices do not require an exterior lever, and as such, may be more compact and can more easily be wall- or ceiling-mounted, leaving floor space unoccupied.
Both ceiling- and floor-mounted electrical lifting devices have a motor and winch assembly attached to a fabric lifting strap. The fabric lifting strap is attached to a sling in which the patient sits or lays to be moved from one position into another. In order to load the patient into the sling, and in regular daily use, caregivers, patients, maintenance personnel, and housekeeping staff may touch or grab the fabric lifting strap multiple times. Unfortunately, fabric lifting straps are exceedingly difficult to properly disinfect.
Although some lifting devices are positioned in family homes, most are used in group settings, such as assisted living facilities, nursing homes, doctor's offices, and hospitals. These group locations may use a single lifting device to transport multiple patients throughout the day. The patients may have different diseases or conditions that can be spread through multiple uses of the same device. Such a spread of potentially dangerous pathogens is undesirable, especially in group locations where widespread sickness could occur.
Therefore, there is a need for a lifting device that minimizes the risk of cross-contamination between patients, as well as between patients and caregivers. The present invention answers that need by providing for a non-porous, completely sealed, plastic lifting strap that can be easily and quickly wiped down with any standard hard surface disinfectant. In addition, the infection control lifting strap of the present invention has a sturdy metal core that is more durable and reliable than a conventional fabric strap.
A support member for use in a patient lifting device is described. The support member includes an improved lift strap having an inner core and an outer plastic layer that can be easily and effectively cleaned with standard disinfectant. The lift strap is secured to a patient lifting device with a spool assembly that guides the lift strap and a belt clamp assembly that compresses the lift strap and holds it in place.
In one embodiment, the support member is used in an electric ceiling- or floor-mounted patient lifting device. The lifting device includes a track component attached to a winch assembly. The winch assembly has an electric motor that raises and lowers the lift strap by means of a spool assembly and belt clamp assembly. The belt clamp assembly attaches to a sling that supports the patient while he or she is displaced.
Still other aspects, features, and advantages of the present invention are readily apparent from the following detailed description, simply by illustrating a number of exemplary embodiments and implementations, including the best mode contemplated for carrying out the present invention. The present invention also is capable of other and different embodiments, and its several details can be modified in various respects, all without departing from the spirit and scope of the present invention. Accordingly, the drawings and descriptions are to be regarded as illustrative in nature, and not as restrictive.
The present invention will be understood more fully from the detailed description given below and from the accompanying drawings of various embodiments of the invention, which, however, should not be taken to limit the invention to the specific embodiments, but are for explanation and understanding only.
A support member, including an improved lift strap, for use in a patient lifting device is described. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the exemplary embodiments. It is apparent to one skilled in the art, however, that the present invention can be practiced without these specific details or with an equivalent arrangement.
The present invention provides a support member for use in a patient lifting device. The support member includes a lift strap having an inner core and an outer non-porous plastic layer and means for securing the lift strap to the patient lifting device. The means for securing the lift strap to the patient lifting device include a cylindrical spool operably connected to a first end of the lift strap, where the spool has at least one strap guard positioned at a distal end of the spool. The means for securing the lift strap to the patient lifting device further include one or more cylindrical thickness rollers having an exterior guiding channel configured to support the lift strap and a belt clamp assembly operably connected to a second end of the lift strap.
Likewise, the present invention provides a patient lifting device for displacing persons between various positions or areas. A patient lifting device in accordance with the present invention includes a track component, an electric motor connected to the track component, a lift strap having an inner core and an outer non-porous plastic layer, means for securing the lift strap to the track component, a belt clamp assembly operably connected to a second end of the lift strap, a lifting frame operably connected to the belt clamp assembly, and a sling. The means for securing the lift strap to the track component include a cylindrical spool operably connected to a first end of the lift strap, where the spool has at least one strap guard positioned at a distal end of the spool. The means for securing the lift strap to the track component also includes one or more cylindrical thickness rollers having an exterior guiding channel configured to support the lift strap and a belt clamp assembly operably connected to a second end of the lift strap.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views,
The lifting frame 130 (spreader bar) provides an interface between the ceiling lift housing component 110 (and the components housed inside as shown in
Spool 370 may have a cylindrical or other rounded edge shape that allows for smooth winding and dewinding of lift strap 360 at a relatively constant speed. Spool 370 has a diameter that maintains a constant shear stress on lift strap 360. Spool 370 is of sufficient diameter that lift strap 360 does not become damaged or destroyed in use by tangling, overlapping, or otherwise winding upon itself. Strap guard 380 may be made of a conductive material, such as aluminum, to prevent the friction of lift strap 360 from generating high temperatures as lift strap 360 passes over guard 380. The aluminum or other conductive material may be used to radiate heat from lift strap 360. By conducting heat from lift strap 360, lift strap 360 will not deform or change in cross-section area, which may affect performance. Lift strap 360 is wound onto spool 370 and is threaded through one or more thickness rollers 390. Lift strap 360 then extends gravitationally downwards to attach, for example, to lifting frame 130.
As shown further in
In conjunction with the large radii components, the support member in the patient lifting device of the claimed invention includes a load cell 909 as shown in
However, the current required to lift the maximum load is dependent upon the (vertical) position of the load over the lifting range of the patient lifting device. At the top of its vertical travel, the ceiling lift may require more than twice the current to lift the same weight as it would when the lift strap is in a fully extended position (patient lift's lowest position). With the lift strap in a fully extended position (lowest position), the effective radius of the spool is a minimum value. As the system lifts a patient, the system retracts the lift strap, and it coils around the spool 370, and the effective radius of the spool 370 increases. This larger radius spool requires a larger force to turn it. The system applies electrical current to turn the spool, and more current is required to apply more force. When lifting a patient from a fully extended position (lowest) to a fully retracted position (highest), the radius of the spool can double. To meet the 150% proof test, the patient lift device of the claimed invention includes a load cell to overcome the current limitations and supply the effective current needed to lift the designated weight (patient) at any point over the lifting range.
Prior systems inefficiently transmit power from an electric motor to a lift belt spool. Often, the efficiency lost in transferring power to the lift belt spool serves to prevent the patient's weight from back-driving the motor and keeps the patient is a stationary position when the lift is idle (i.e., the lift is not being raised or lowered). The patient lifting device of the claimed invention utilizes a high efficiency gearbox 1111 (shown in
The high efficiency gearbox 1111 provides additional benefits. Regulatory agencies require ceiling lifts to include an emergency lowering function (“e-down”) when power is cut off from the system (such as in a power failure, for example). Prior ceiling lifts do not allow back-drive through the transmission. That is, the transmission of prior systems engages even when no power is applied. To lower a patient in an emergency lowering scenario, prior systems utilize a battery backup to provide power to the motor to lower the patient. With the high efficiency gearbox 1111 of the claimed invention, in the event of a power failure, the system can simply release the electro-mechanical brake 1133 and passively lower the patient with the lowering function force provided exclusively by gravity. The claimed invention uses no additional drive and no additional power source to lower a patient when power is removed from the system, such as in an emergency.
In addition to clamping the lifting frame 130 (spreader bar) to the lifting strap 410 to reduce perforations in the strap 410 and the possibility of infection through bacterial infiltration, the claimed invention incorporates a similar clamping mechanism in upper limit switch 1313 shown in
The manner in which the lift strap attaches to the spool can affect performance and durability of the lift strap and the patient lift device in general as well as the comfort of the patient. In previous systems, a lift strap could be attached to the spool on the surface of the spool. In previous systems, the attachment point is necessarily raised above the surface of the spool. As the spool rotates and the lift strap coils onto the spool and then onto itself, the strap spools unevenly due to the raised attachment point. The motor controller experiences a spike in the torque feedback received, which in turn produces a spike in the applied current to the patient lift. The patient experiences a small oscillation/jerk corresponding to the spike in applied current.
As shown in
As shown in the cross sectional detail of
As the eccentric spool 370 rotates, the lift strap 360 initially drapes and coils onto the spool 370 at exit point 828, and the addition of the thickness of the lift strap 360 to the slightly lower spool surface (of the arc beginning at the exit point 828) makes the entire effective radius equal to the nominal spool radius R. The spool configuration, including the attachment point 818 and the eccentric radius of the spool provides a uniform surface upon which the lift strap 360 drapes and coils onto the spool and eliminates the applied current spikes, the oscillation/jerk of the lift strap during travel, and patient discomfort or negative effects resulting from the uneven travel.
As outlined above with regard to
The present invention has been described in relation to particular examples, which are intended in all respects to be illustrative rather than restrictive. Moreover, other implementations of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. Various aspects and/or components of the described embodiments may be used singly or in any combination. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.
This application is a continuation-in-part application of U.S. patent application Ser. No. 12/558,077, filed on Sep. 11, 2009, which claims the benefit of priority to U.S. Provisional Patent Application No. 61/095,970, filed on Sep. 11, 2008. The entire contents of these applications are incorporated by reference below.
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Number | Date | Country | |
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20160000625 A1 | Jan 2016 | US |
Number | Date | Country | |
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61095970 | Sep 2008 | US |
Number | Date | Country | |
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Parent | 12558077 | Sep 2009 | US |
Child | 14697848 | US |