The present system relates to the wireless control of functions of a patient support apparatus and to systems that assist with the movement of patients who are partially or completely incapacitated. More specifically, the present disclosure relates to a wirelessly controlled system coupled to a patient support apparatus and configured to reposition a patient relative to the longitudinal length of the patient support apparatus.
From time to time, patients on a patient support apparatus, such as a hospital bed, who are partially or completely incapacitated need to be moved or repositioned. For example, in some cases, a patient may have slid down, slumped, or otherwise moved toward a foot end of the patient support apparatus, for example. This may result from raising a head section of the patient support apparatus and the patient may need to be repositioned toward the head end after the head section is lowered back down. In other cases, a patient may need to be moved to a different bed.
In repositioning or moving a patient, a caregiver such as a nurse, for example, will grip the patient and pull, slide, or roll the patient to the new position. For larger patients, the caregiver may summon assistance from other nurses, assistants, orderlies, or the like. In some cases, a piece of fabric referred to as a draw-sheet may be positioned under the patient and used by the caregivers as an aid to repositioning the patient. The draw-sheet may be gripped by the caregiver(s) and used to lift and reposition the patient or the sheet may be pulled over the surface of the patient support apparatus to reposition the patient.
The present invention comprises one or more of the features recited in the appended claims or the following features or combinations thereof:
A patient support apparatus comprising a pull-up-in-bed system for repositioning a patient on the patient support apparatus is provided. The pull-up-in-bed system may comprise a retractor, a tether coupled to the retractor at a first end of the tether and configured to be retracted by the retractor. The pull-up-in-bed system may further comprise a sheet attachment device coupled to a second end of the tether, the sheet attachment device configured to engage a sheet under the patient being repositioned.
The sheet attachment device may comprise a release handle coupled to a U-shaped frame and moveable between a first position and a second position. The sheet attachment device may further comprise a roller coupled to the U-shaped frame between the two legs of the U-shaped frame, the roller being rotatable relative to the U-shaped frame. The sheet attachment device may include a ratchet mechanism which permits rotation of the roller relative to the U-shaped frame in a first rotational direction and impeding rotation of the roller in a second, and opposite direction. The ratchet mechanism may be releasable relative to the roller thereby permitting free rotation of the roller in both the first and second directions. A linkage may connect the release handle to the ratchet mechanism such that when the release handle is in a first position, the ratchet mechanism is engaged to prevent rotation of the roller in the second direction and when the release handle is in a second position, the ratchet mechanism is released to permit rotation of the roller in the second direction. The release mechanism may be biased toward the engaged position by a spring. In other embodiments, a wrap spring may be provided to lock the roller from rotating relative to the frame. In such embodiments, the handle may be moveable to release the wrap spring to allow the roller to rotate relative to the frame.
The sheet attachment device may further comprise a retracting pin moveably coupled to the U-shaped frame and moveable between a first position wherein the retracting pin extends into a cavity on the side the U-shaped frame and a second position wherein the retracting pin retracts into the U-shaped frame so that the retracting pin does not extend into the cavity. The retracting pin may be configured to engage an edge of a lug on a headboard of the patient support apparatus to retain the sheet attachment device onto the headboard until the retracting pin is retracted to allow the sheet attachment device to be removed from the headboard. The retracting pin may be coupled to the release handle such that when the release handle moves between the first and second positions, the retracting pin moves between the retracting pin's corresponding first and second positions. The retracting pin may be retracted independently of the release handle by exerting an external force along an axis of the retracting pin. Also, the retracting pin may cam against the lug as the sheet attachment device is placed into the storage space of the headboard thereby moving the retracting pin from the first position to the second position until the retracting pin clears the lug and is free to extend past a lower edge of the lug. The retracting pin may be biased to the first position by a spring.
A sheet on the patient support device may be wound around the roller as the roller is rotated in the first direction relative to the frame. After a single revolution, the sheet may wrap upon itself. The sheet may stay wrapped upon the roller until the ratchet mechanism is moved to the second position releasing the roller. The sheet may then be unwound from the roller to disengage the sheet from the roller. The roller may rotate in the second direction as the sheet is unwound. The roller may have a pliable external surface to provide improved gripping of the sheet to the roller during engagement of the sheet and roller. The external surface of the roller may comprise Santoprene® or a similar material.
The U-shaped frame may be a multi-piece construction including a front housing and a back housing coupled to the front housing. The front housing and back housing may be a compression molded, glass-filled polyester material. In some embodiments, the front and back housing may be machined from aluminum or other metal. It should be understood that there are any of a number of materials and processes that may be used to construct pieces of the U-shaped frame. The release handle, ratchet mechanism, springs, and linkage may be retained between the front and back housings when the front and back housings are coupled together.
The tether may be coupled to the sheet attachment device by a bracket that is retained between the housings. The tether may comprise a woven nylon belt. The tether may comprise a coating or other protective covering such as urethane. The coating may provide a smooth outer surface and thereby reduce soiling or contamination. The tether may further comprise instructions related to the use of the pull-up-in-bed system. In some embodiments, the instructions may be on a label that is adhered to the belt prior to applying the urethane coating. In other embodiments, the instructions may be silk-screened on the belt. The tether may pass over the headboard. A headboard configured to withstand the forces applied by the retraction of the tether and having an integrated roller may be used. For example, the headboard of a copending related U.S. patent application titled “HEADBOARD FOR A PULL-UP-IN-BED SYSTEM,” with a Ser. No. 11/314426 , filed concurrently herewith on Dec. 21, 2005, and hereby incorporated herein by reference.
The retractor may comprise a prime mover, a retraction mechanism coupled to the prime mover, and a controller electrically coupled to the prime mover and configured to receive inputs from a user and a number of other hardware or sensors. The controller may process the inputs and provide output signals to the user, the prime mover, and a number of other hardware or sensors.
The retraction mechanism may comprise a clutch, a spool, and a retraction spring. The clutch may be coupled to the prime mover to receive rotational output therefrom. The clutch may transmit the rotational output from the prime mover to the spool until the clutch is selectively engaged to prevent transmission of output from the prime mover. The clutch may comprise a wrap spring, an input coupler, an output coupler, and an outer housing coupled to the wrap spring. The wrap spring may couple the input coupler to the output coupler such that rotation from the input coupler is transferred to the output coupler. The outer housing may be configured to release the wrap spring so that rotation from the input coupler is not transferred to the output coupler. The outer housing may be engaged by an engagement arm to release the wrap spring. The engagement arm may engage an engagement surface on the outer housing to release the wrap spring. The engagement arm may be configured to move between a first position in which the engagement arm engages the engagement surface of the outer housing and a second position in which the engagement arm is disengaged from the outer housing. In some embodiments, the engagement arm may be coupled to a solenoid, the solenoid configured to move the engagement arm between the first and second positions.
The spool may be coupled to an output coupler from the clutch to receive rotational output transmitted by the clutch. As the spool rotates in a first direction, the tether wraps about the spool. The spool may be coupled to a retraction spring which resists extension of the tether from the spool and urges retraction of the tether by biasing the spool to rotate in the first direction to retract the tether.
The prime mover may comprise an electric motor configured to provide rotational output, a gearbox coupled to the electric motor and configured to alter the speed of the rotational output from the motor. The motor may be a brushless, reversible DC motor. In some embodiments, the motor may be an AC motor. In some embodiments, the motor may receive power from the controller. In other embodiments, the motor may receive power directly from the patient support apparatus and the controller may provide an excitation signal to activate the motor. In still other embodiments, the motor may have an integrated power supply and receive power directly from a main power source such as a wall outlet, for example. In some embodiments, the controller may provide a supervisory signal that allows the motor to be activated. The gearbox may be an inline speed reduction apparatus. In other embodiments, the gearbox may transfer the output rotation from the motor at an angle, such as ninety degrees.
The controller may comprise a field programmable gate array (FPGA) logic circuit. In some embodiments, the controller may comprise a microprocessor or microcontroller coupled to a control network of the patient support apparatus. The controller may receive signals from various sensors and input devices and process those signals to provide output signals to the prime mover, solenoid, and an audible alarm. The sensors may include an optical detector, a potentiometer, and a bed status sensor. The optical detector detects that the tether is in the fully retracted position by detecting the presence of an end-of-travel indicator. The potentiometer may provide a feedback signal to the controller which is indicative of the amount of tether which has been extended from the spool by sensing the amount of rotation of the spool. The bed status sensor may be configured to receive a signal from the patient support apparatus indicating that the patient support apparatus is positioned to perform a patient repositioning operation or that a patient repositioning operation should not be performed. For example, if the head section of the patient support apparatus is inclined, the pull-up-in-bed system may not operate due to a signal from an associated bed status sensor. Likewise, if another bed motor other than the motor associated with the pull-up-in-bed system is active, the pull-up-in-bed system may not activate. It should be understood that there are a number of conditions which may be sensed to provide a signal to the controller not to operate the pull-up-in-bed system.
In some embodiments, a control system for the patient support apparatus may comprise a device operable to send a wireless signal, a wireless receiver, and a circuit operatively coupled to the wireless receiver. The device may control at least one function of the patient support apparatus. The wireless receiver may be coupled to the patient support apparatus and configured to receive the wireless signal from the device. The circuit may have a first mode of operation in which the circuit processes the wireless signal and associates the device with the patient support apparatus. The circuit may have a second mode in which the circuit controls the patient support apparatus to operate at least one function of the patient support apparatus in response to the wireless signal.
The control system may further comprise a visual indicator in communication with the circuit and configured to provide an indication that the device has been successfully associated with the patient support apparatus.
The circuit may comprise a memory device configured to store an association parameter transmitted by the device. In some embodiments, the device may transmit the wireless signal at a plurality of frequencies. The circuit may further comprise multiple memory devices and each memory device may store a different association parameter for each of the plurality of frequencies at which the device transmits. The circuit may further comprise multiple visual indicators, each visual indicator being associated with a respective frequency at which the device transmits and the indicators may be operable to provide an indication that the device has been successfully associated with the circuit at a particular frequency.
In another embodiment, a control system for the patient support apparatus may comprise a plurality of wireless receivers, each wireless receiver configured to alternately receive a signal transmitted at a plurality of wireless signals. The control system may further comprise a circuit operatively coupled to the wireless receivers. The circuit may sequentially poll combinations of each wireless receiver at each frequency until a signal of suitable quality is detected. The circuit may maintain the receiver and frequency combination at which the signal of suitable quality is detected.
In some embodiments, in order to determine if the signal is of suitable quality, the circuit may analyze the wireless signal to determine if the signal includes a signal source identifier that the circuit recognizes. The circuit may further analyze the signal to determine if the signal source identifier transmitted in a first transmission matches the signal source identifier in a second transmission immediately following the first transmission.
In some embodiments, the wireless receivers may each comprise an antenna tends to be immune to a particular interference source. In some embodiments, the circuit may comprise a printed circuit board. The antenna may comprise a trace of a printed circuit board or an external wire coupled to the circuit. The source of wireless signal transmitted over a plurality of frequencies may be a device that transmits the signal to control a function of the patient support apparatus. The function of the patient support apparatus may be a motor. The motor may be a part of a pull-up-in-bed system.
In some embodiments, the signal may be an infrared signal. A wireless transmitter may be coupled to the sheet attachment device or other user input device and configured to send a signal to operate a function of the patient support apparatus only if an appropriate sequence of user input devices are activated to prevent unintentional operation. In some embodiments, an enable input may be required to be activated prior to a function input and the function input may be required to activated within a predetermined time of the enable input for the function to be activated by the control system. The circuit may be configured to determine that the signal includes is from a device which has been previously associated with the circuit before activating the function of the patient support apparatus.
The control system may include a memory to store an association variable of the transmitter, such as a serial number of the transmitter, for example. In some embodiments, the device may transmit a signal redundantly over a plurality of frequencies. The signal may be a radio frequency signal
In an illustrative embodiment, a wireless receiver may be coupled to the controller and configured to receive a wireless signal from the wireless transmitter and process that signal to provide an input signal to the controller to indicate that the user has activated the pull-up-in-bed system. The wireless receiver may comprise multiple antennae, an antennae switching system, a FPGA, a learn switch, an electrically erasable programmable read-only memory (EEPROM), and one or more light emitting diodes (LEDs). The learn switch may be moveable between a learn position and a normal position. The FPGA may be configured to receive and store a unique identifier for the wireless transmitter hardware when the learn switch is in the learn position and store this identifier in the EEPROM. The FPGA may be configured to compare the stored identifier with an incoming identifier that is part of a wireless signal from the wireless transmitter uniquely indicative of the wireless transmitter hardware being used. When the learn switch is in the normal position, the FPGA may compare the stored identifier to the incoming identifier to confirm that the signal is from the appropriate transmitter. The LEDs may provide visual indication to a user of the status of the wireless receiver with respect to a mode, such as a learn mode, for example, and whether the wireless receiver has successfully acquired and stored the identifier of the wireless transmitter.
The retractor may be coupled to a frame of the patient support apparatus. In some embodiments, the retractor may be coupled to a frame independent of a weighing frame of the patient support apparatus and the sheet attachment device may be stowed on the headboard which is on the weighing frame of the patient support apparatus. In such embodiments, the retractor is configured to control retraction of the tether such that during periods of non-use the tether remains slacked and thereby reduces the amount of force on the weighing frame thereby reducing interference with the performance of a weighing system of the patient support apparatus which operates to determine the patient's weight.
While the present invention discloses the use of a wireless signal to operate a pull-up-in bed function of the patient support apparatus, it should be understood that the wireless functionality of the system may be applied to the operation of any of a plurality of functions of the patient support apparatus. For example, articulation functions of a patient support apparatus such as head elevation, apparatus height, leg section articulation or other articulation functions may be activated by the system. In some embodiments, the wireless system may be applied to operate other functions such as patient controlled devices including television channel up, channel down, channel select volume up, volume down, radio, audio, direct lighting, or indirect lighting or to activate or operate a nurse call system.
Additional features of the disclosure will become apparent to those skilled in the art upon consideration of the following detailed description of illustrative embodiments exemplifying the best mode of carrying out the pull-up-in-bed system as presently perceived.
The detailed description particularly refers to the following figures in which:
A patient support apparatus 10 including a pull-up-in-bed system 28 is shown in
Referring now to
Upon completion of the repositioning cycle, the sheet attachment device 24 is detached from the sheet 34. The sheet attachment device 24 is configured to be stowed in the headboard 22 when not in use as shown in
Referring now to
The front housing 40 and the back housing 42 experience significant stresses due to the loads transferred therethrough. In the illustrative embodiment of
When the housings 40, 42 are coupled together, the roller 46 is retained by the housings 40, 42 and is rotatable relative to the housings 40, 42 about an axis 120 which is substantially coincident with the centerline of the roller 46 along its longitudinal length as shown in
Referring again to
While the roller 46 freely rotates about axis 120 in one direction, a ratchet gear 70 which is coupled to the roller 46 is engaged by a retractable pawl 76 to prevent rotation in the opposite direction about axis 120. Referring now to
Rotation in a second direction opposite the first direction, and depicted by arrow 136 in
When the pawl is engaged as shown in
Referring now to
When the handle 94 is actuated from the first position to the second position, the resulting motion moves the brackets 98. The brackets 98 each further include an aperture 148. The aperture 148 is configured to receive a pivot pin 110 which is coupled to a pivot link 100. The aperture 148 has an inside diameter which is slightly larger than the outer diameter of the pivot pin 110 so that the pivot pin 110 is free to rotate within the aperture 148. The pivot link 100 also includes an aperture 150 which receives a pivot pin 152 coupled to the front housing 40. Like the relationship of aperture 148 and pivot pin 110 discussed above, the aperture 150 inside diameter is sized slightly larger than the outside diameter of the pivot pin 152 so that the pivot link 100 is free to pivot about the pivot pin 152. Thus, when handle 94 is actuated by force 140 the resulting motion is translated through the bracket 98, pivot pin 110 to pivot the pivot link 100 about the pivot pin 152.
The pivoting of the pivot link 100 results in the linear movement of a lateral bracket 112 which is pivotably coupled to the pivot link 100. The lateral bracket 112 has yet another aperture (not seen) which receives another pivot pin 110 on the pivot link 100. The aperture on lateral bracket 112 receives the pivot pin 110 similar to the interaction of aperture 148 and pivot pin 110 discussed above such that the pivot pin 110 is free to pivot within aperture on the lateral bracket 112. The lateral bracket 112 then becomes a follower relative to movement of the pivot link 100. The lateral bracket 112 floats relative to the front housing 40 due to the support of the pivotable coupling of the lateral bracket 112 to the pivot link 100 through the pivot pin 110 and support of the lateral bracket 112 by the retaining pin 114 through the slot 154 of the retaining pin 114 engaging the pin 156 of the lateral bracket 112. Additional support is provided by the bias of the spring 74 which places tension on the ratchet release cable assembly 78. The tension developed by spring 74 also supports lateral bracket 112 and allows lateral bracket 112 to continue to float if the retaining pin 114 is displaced by an external force not transmitted through handle 94.
The resulting motion of lateral bracket 112 is transferred to the ratchet release cable assembly 78 and a retaining pin 114. The retaining pin 114 has a slot 154 which is configured to receive a pin 156 coupled to the lateral bracket 112. Movement of the lateral bracket 112 pulls the retaining pin 114 so that the retaining pin 114 is retracted from the cavity 502. The retaining pin 114 is biased to extend into the cavity 502 by a spring 116 which interfaces with the housing 40 at one end and with a shoulder 158 of retaining pin 114. Retraction of the retaining pin 114 into the housings 40, 42 results in compression of the spring 116. Upon subsequent release of the force on retaining pin 114, the spring 116 urges the retaining pin 114 to extend from the housings 40, 42 into the associated cavity 502.
Each retaining pin 114 extends into the respective cavity 502 of housing 40 and when the sheet attachment device 24 is moved in a downward direction into the cavity 160, shown in
In addition to retracting the retaining pins 114, movement of lateral bracket 112 simultaneously moves the pawl 76 to the retracted position permitting the roller 46 to move freely and thereby unspool the sheet 34 from the roller 46 as shown in
Referring now to
The retractor 30 is configured to be selectively actuable to retract the tether 26 and thereby provide the locomotion to reposition a patient 36. Referring now to
The clutch 186 is configured to be selectively actuable to engage or disengage the prime mover 180 relative to the spool core 178. The clutch 186 is a wrap spring type clutch such as the Danaher Motion PSI 5 clutch Danaher part number 205-10-022. While the illustrative embodiment is a wrap spring clutch, it should be understood that a number of other clutches or motion control devices may be used to disengage output from the prime mover 180 to the remainder of the retractor 30.
When the prime mover 180 outputs torque in the direction represented by arrow 194, a wrap spring (not shown) internal to the clutch 186 locks an input portion of the clutch 186 to an output portion of the clutch 186. Torque is then transmitted through the clutch to a coupler 196. Upon completion of the repositioning cycle, the prime mover 180 output is reversed and torque is applied in the direction opposite 194. At the end of the reposition cycle, the tether 26 is under tension. By operating the prime mover 180 in the direction opposite 194, the tension on tether 26 is relieved. The clutch 186 further includes an outer housing 198 which has slots 200 on opposite ends and aligned with the keyway 192 when the clutch 186 along an axis perpendicular to the axis of rotation 210. The slots 200 are configured to receive tangs 212 of the wrap spring (not shown) internal to the clutch 186.
The output from the clutch 186 is transmitted through a slotted output collar 214 (see
The clutch 186 is disengaged when torque from the prime mover 180 is not to be transferred to spool core 178. Clutch 186 is disengaged by the action of an engagement assembly 220 which includes a solenoid 222, a retractable plunger 224 coupled to the solenoid 222 at a first end and coupled to an engagement arm 226 at the second end. The engagement arm 226 is pivotably coupled to a base bracket 228 which supports the clutch 186 and various other components of the retractor 30. The engagement arm 226 is supported by a pivot pin 230 which is coupled to the base bracket 228. The pivot pin 230 has a shoulder 232 which locates the pivot pin 230 axially on the base bracket 228. The engagement arm 226 is separated from the shoulder 232 by a washer 234 and is retained on the pivot pin 230 by a snap-ring 236 which is configured to mate with a groove 238 on the pivot pin 230.
The engagement assembly 220 is configured to move the engagement arm 226 between a first position wherein the engagement arm 226 is engaged with the clutch 186, shown in solid in
In operation, the clutch 186 is disengaged by engagement of the engagement arm 226 with the engagement surface 242 and slight rotation of the output shaft 188 in the direction of the torque 194. The relative motion of the output shaft 188 to the outer housing 198 of the clutch 186 urges the wrap spring (not shown) to expand and disengage permitting the output collar 214 to rotate freely relative to the output shaft 188 of the prime mover 180. Movement of the solenoid 232 to the second position results in disengagement of the engagement arm 226 from the outer housing 198 which thereby releases the wrap spring (not shown) allowing it to engage and couple the output shaft 188 to the output collar 214. The solenoid 232 is a DC coiled device which, when energized, magnetically urges the plunger 224 into the coil body. This movement is transmitted to the engagement arm 226 causing the engagement arm 226 to pivot about the pivot pin 230 to the second position wherein the engagement arm 226 is disengaged from the outer housing 198. Thus, engagement arm 226 is normally in the first position engaging the outer housing 198 of clutch 186. While the illustrative embodiment utilizes a solenoid, any of a number of actuation methods may be used which move an engagement member such as the engagement arm 226, for example, between an engaged position and a disengaged position. Control of the actuation of the solenoid 226 is provided by a controller 246 which is further discussed below.
Referring again to
In addition to passing through the coupler 196, the shaft 248 passes through a washer 258, a bushing 260, and a first flange 262 of the base bracket 228. The washer 258 is configured to prevent wear between the coupling 196 and the first flange 262 of the base bracket 228. The bushing 260 is a flanged bushing which is configured to mate with an aperture 264 in first flange 262. The bushing 260 is inserted into the aperture 264 such that the flange portion of the bushing 260 is on the side of the flange 262 of base bracket 228 opposite the washer 258. The inside diameter of the bushing 260 is sized to support the shaft 248 as a bearing surface thereby permitting the round sides of the shaft 248 to be supported by the busing 260 while the shaft 248 rotates. The shaft 248 also passes through a spool flange 266, the spool core 178, and a second spool flange 266.
Continuing to refer to
The retraction spring assembly 276 is a flat coiled steel spring 280 which is retained by a retainer 284 having multiple flanges 286 which hold the spring 280. The spring engagement portion 252 is received in the aperture 278 and the slot 254 in the spring engagement portion 252 engages a tang (not shown) which is formed at the inner coil of the spring 280 and is configured to engage the slot 254. The retraction spring assembly 276 is held fixed by a bracket 288 which is coupled to base bracket 228. When the shaft 248 rotates in the direction opposite torque 194 slot 254 and the tang on spring 280 also rotates. Because the spring 280 is retained, potential energy is developed in the spring 280. This potential energy urges the spring 280 and thereby, the shaft 248 and spool core 178, to maintain tautness in the tether 26.
In use, when the prime mover 180 is disengaged from the spool core 178, the retraction spring assembly 276 maintains some tension in the tether 26, but allows the tether 26 to be extended from the retractor 30 by a user. In addition, when the retractor 30 and headboard 22 are mounted on different frames of the patient support apparatus 10 that move relative to one another, the operation of the retraction spring assembly 276 permits the tether 26 to extend during relative movement of the frames away from one another without damaging the retractor 30. The constant bias of the retraction spring assembly 276 results in the tether 26 being retracted when the frames move toward one another.
The spool core 178 further includes two threaded holes 274 as shown in
Further control of the operation of the tether 26 is provided by a guide roller 290 which is rotatably coupled to the base bracket 228. The guide roller 290 provides a substantially constant exit angle of the tether 26 from the base bracket 228 regardless of how much or how little of tether 26 is wound upon spool core 178 by sandwiching the tether between the spool core 178 and a clamping plate (not shown). The tether 26 passes through an aperture 292 in base bracket 228 and another aperture 294 in a plate 296 which is coupled to the base bracket 228 by several fasteners 298. The plate 296 serves as a mechanical stop for the tether 26 so that the tether 26 is not retracted excessively. The plate 296 aperture 294 is sized to prevent a stop 300 coupled to the tether 26 from passing through the aperture 294. This limits the retraction of the sheet attachment device 24 so that a patient is not retracted such that they contact the headboard 22.
The size of the aperture 294 is such that as the tether 26 is unwound from the spool core 178, the angle of interaction between the tether 26 and the aperture 294 changes and increases the frictional forces on the tether 26, thereby reducing the amount of force transmitted through the tether 26 to reposition the patient. The addition of the guide roller 290 provides a constant exit angle for the tether 26 through the aperture 294. The guide roller 290 is supported by a shaft 310 having a head 318 at one end and a retaining ring groove 316 proximate the end opposite the head 318. The shaft 310 is ad-shaped shaft which engages an aperture 312 in the second flange 282, passes through the guide roller 290, and another aperture 312 in the first flange 262. The apertures 312 are also d-shaped such that the shaft 310 is restrained from rotation relative to the flanges 262, 282. The guide roller 290 has a circular hollow core along it's longitudinal axis which and is free to rotate about it's longitudinal axis. The guide roller 290 further includes a flange 320 proximate each end of the guide roller 290. The flanges 320 assist in retaining the guide roller 290 between the flanges 262, 282. The shaft 310 is retained relative to the first flange 262 by a retaining ring 314 which is configured to engage the groove 316 on the shaft 310 and prevent longitudinal movement of the shaft 310 relative to the base bracket 228.
While the stop 300 provides a mechanical safety to prevent excessive retraction of the tether 26, further control of the retraction is achieved by an optical sensor 320 and/or a potentiometer 322. The optical sensor 320 is coupled to a bracket 326 by several fasteners 324 and the bracket 326 is coupled to the base bracket 228 by several more of the fasteners 324. The optical sensor 320 is U-shaped with one leg of the u-shape including an optical emitter. The opposite leg of the u-shape includes an optical detector. The optical sensor 320 is configured such that the tether 26 passes between the legs of the optical sensor 320 as the tether 26 retracts. When the tether 26 is in a fully retracted position, an aperture 328 is positioned such that the optical detector is in communication with the optical emitter. The optical sensor 320 is electrically coupled to the controller 246, which is discussed in further detail below, and is configured to provide a signal to the controller 246 when the tether 26 is in the fully retracted position.
The potentiometer 322 is coupled to a bracket 330 which is coupled to the base bracket 228. The input shaft 332 of the potentiometer is coupled to the shaft 248 so that the potentiometer 322 input shaft 332 rotates in unison with the shaft 248. The potentiometer 322 is electrically coupled to the controller 246 and is configured to provide a signal to the controller 246 indicative of the position of the potentiometer 322 which directly correlates to the amount of extension or retraction of the tether 26. The controller 246 is configured to process the signal from the potentiometer 322 and/or the optical sensor 320 to determine the state of the retractor 30 and provide control signals to the prime mover 180 based on the signals from the potentiometer 322 and/or the optical sensor 320.
The controller 246 is included as part of an exemplary control board assembly 332 which is coupled to a circuit board bracket 334 which is coupled to the base bracket 228 as shown in
Additional hardware associated with the operation of the pull-up-in-bed system 28 includes the optical detector, 320, a receiver assembly 338, lock-out switch 340, audible alarm 342, and status indication 344 which are each electrically coupled to the controller 246 and configured to provide the controller 246 input signals. The controller 246 is configured to process these signals and determine the appropriate outputs to provide operation of the pull-up-in-bed system 28.
Illustrative circuitry of the control board assembly 332 associated with the driving of solenoid 222 is shown in
Exemplary circuitry of the control board assembly 332 for processing signals from the optical detector 320 is shown in
Illustrative circuitry of the control board assembly 332 that may be used to receive the signal from the lock-out switch 340 is shown in
A connector P7, shown in
The remaining figures show various other exemplary circuitry which may be utilized in the control board assembly 332 to control the operation of the pull-up-in-bed system 28.
Referring now to
The transmitter assembly 346, shown in
In one illustrative embodiment of circuitry shown in
Referring to
In the decision step 368, the control routine 358 monitors the status of the run switch 356. If the run switch 356 and a timer delay of 34. 13 milliseconds, for example, has been achieved, the control routine advances to a process step 370. If the conditions of the decision step 368 have not been met, then the control routine 358 returns to the decision step 366. At the process step 370 the FPGA 348 sends a packet of data to an ASK transmitter 350 which results in a first channel transmission of the run signal. The control routine 358 then advances to the next step which is a processing step 372. In the processing step 372, the control routine 358 switches channels to the ASK transmitter 350 opposite the previous channel transmission and resets the timers. The control routine 358 then returns to the decision step 366 to begin another loop. Each of the two ASK transmitters 350 operate at different frequencies, one at 315 MHz and the other at 916 MHz, for example. The transmitter assembly 346 transmits signals at two different frequencies having differing susceptibility to external interference such that if one frequency is disrupted, the other may be transmitted properly. While the illustrative embodiment utilizes two frequencies, 315 MHz and 916 MHz, for example, it should be understood that any of a number frequencies may be utilized redundantly to provide overcome potential external interferences.
A second control routine 374 shown in
Referring now to
Each signal is filtered by the associated SAW 424, 426 and is passed from the respective SAW to the appropriate receiver 428 or 430. The SAW 424 is dedicated to the 315 MHz frequency and is coupled to the receiver 430. Similarly, the SAW 426 is dedicated to the 916 MHz frequency and is coupled to the receiver 428. The receivers 428, 430 process the radio frequency signal at their respective frequencies and pass the converted signal to the FPGA 432 which processes the signal according to the control routine 434 of
The receiver assembly 338 further comprises a hi electrically erasable programmable read-only memory (EEPROM) 464, a lo EEPROM 466, a learn switch 468, a learn light emitting diode (LED) 470, a hi done LED 472, and a lo done LED 474. The EEPROMs 464, 466 are used to store a serial number transmitted in the signals from the ASK transmitters 350 with the hi EEPROM 464 storing the serial number at the 916 MHz frequency and the lo EEPROM 466 storing the serial number at the 315 MHz frequency. The learn switch 468 is moveable between a first position wherein the receiver assembly 338 is configured to learn the serial numbers of the respective ASK transmitters 350 and a second position wherein the receiver assembly 338 is configured to process signals from the ASK transmitters. The learn LED 470 provides a visual indication that the transmitter has completed learning the serial numbers. The hi done LED 472 and lo done LED 474 provide visual indications that the serial number has been learned at the respective frequencies. The process for learning the serial number is also part of control routine 434 discussed below.
Referring now to
At the decision step 444 the control routine 434 determines if the learn mode is complete by checking a binary variable “done”. If “done” is set, the control routine 434 branches back to step 438 and continues to loop until a status change such as the learn switch 468 being transitioned from the first position to the second position is detected. If the learn process is not complete and “done” is null, the control routine 434 proceeds to a decision step 446 wherein the status of the “got once” variable is analyzed. If the “got once” variable has not been set, then the control routine 434 proceeds to a process step 448 wherein the serial number is written to the EEPROMs 464, 466, the timer is reset, the “got once” variable is set, and a signal is sent to freeze the antenna switches 422, 422. The control routine 434 then proceeds to the decision step 438. If the “got once” variable is determined to be set at the decision step 446, then the control routine 434 proceeds to decision step 450 to determine if the serial number in the header matches a stored serial number. If it does not, then the control routine 434 loops back to the decision step 438. If the serial does match on this second pass, the control routine 434 proceeds to a process step 452 where the “done” variable is set and the control routine 434 returns to the decision step 438.
If the control routine 434 determined at the step 442 that the learn switch 468 was in the second position corresponding to a normal mode, then the control routine 434 advances to the decision step 454 where the “got once” variable is analyzed as shown in
Another control routine 476 runs continuously checking the status of the learn switch 468. At a decision step 478 the current status of the switch is compared against the previous status. If the switch status has not changed, then the control routine 476 loops back to step 478. If the current status of the switch has changed from the previous status, the control routine 476 proceeds to a process step 480 where the “done” and “got once” variables are reset. The control routine 476 then loops back to decision step 478.
The FPGA 432 contains unification logic (not shown) which maintains the antenna switch 422 configuration locked as long as one of the antennae 418, 420 signals are active. If neither signal is active, the antenna switches 422 are shifted and the FPGA 432 checks for an active signal again. This allows the rotation of the frequencies across both the antennae 418, 420 to optimize the antennae/frequency configuration. The system constantly checks for an appropriate signal to forward to the controller 246.
Similarly, the FPGA 432 will forward the run signal to the controller 246 if either one or both of the receivers 428, 430 has received two sequential matching serial numbers from a corresponding transmitter 350. Otherwise, the run signal is not transmitted.
Once the receiver assembly 338 determines that a valid run signal has been transmitted, the receiver assembly 338 signals the controller 246 to run the retractor 30. The controller 246 processes this signal according to the control routine 386 shown in
If the bed status indicator 344 is not active, the control routine 386 progresses to a process step 398 where the solenoid 222 is energized to disengage the engagement arm 226 from the clutch 186 and the motor 182 is activated to provide output torque 194. The control routine 386 then advances to a decision step 400 where the run signal is again analyzed. If the run signal is still active, the control routine loops back to step 390 to perform another series of checks. If no run signal is present, the control routine progresses to a process step 410 where the signal to the motor 182 is set to null. Then the control routine 386 progresses to a process step 412 where the solenoid 222 is de-energized allowing the engagement arm 226 to engage the engagement surface portion 242 of the outer housing 198 of the clutch 186. The control routine 386 then progresses to a process step 414 where the motor 182 is signaled to run in reverse for a period of time sufficient to disengage the clutch 186 thereby releasing slack in the system and freeing the retraction mechanism from the prime mover 180
While the present invention discloses the use of a wireless signal to operate a pull-up-in bed function of the patient support apparatus, it should be understood that the wireless functionality may operate any of a number of functions of the patient support apparatus. In some embodiments, for example, articulation functions of a patient support apparatus such as head elevation, apparatus height, leg section articulation or other articulation functions may be activate by use of the system. In some embodiments, the wireless system operate other functions such as patient controlled devices including television channel up, channel down, channel select volume up, volume down, radio, audio, direct lighting, or indirect lighting or to activate or operate a nurse call system.
Although certain illustrative embodiments have been described in detail above, variations and modifications exist within the scope and spirit of this disclosure as described and as defined in the following claims.
This application claims the benefit, under 35 U.S.C. §119(e), of U.S. Provisional Patent Application Ser. No. 60/638,591 filed Dec. 23, 2004 which is hereby incorporated by reference herein in its entirety.
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