Articulated bed with customizable remote control

Information

  • Patent Grant
  • 5544376
  • Patent Number
    5,544,376
  • Date Filed
    Monday, January 31, 1994
    30 years ago
  • Date Issued
    Tuesday, August 13, 1996
    28 years ago
Abstract
In an articulated bed having a motor for raising and lowering the bed, a control circuit operated by the user has first user memory for storing a first user variable indicating a user-selected first preferred bed position and a recall button by which the user can command that a handler routine in the control circuit return the bed to the first preferred bed position indicated by the first user variable. Further, the control circuit can have a tracking memory for frequently storing a tracking variable indicating the current position of the bed and a "store" or "program" button or control by which the user can command that the first user variable be set to equal the current tracking variable. Thus, any time the bed is in a position preferred by the user, the user can push the "store" button to store a user variable indicating the preferred bed position in the controller's memory; then afterwards the user can have the bed return to that preferred position by pressing the "recall" button.
Description

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to articulated beds adjustable by electric motors or their equivalent to support the person in the bed in different positions as desired, and more specifically to beds that can be operated by a handheld unit coupled to the bed by a wire or wireless link.
2. Description of Related Art
Although adjustable beds have long been found useful in hospital and institutional settings, in recent years such beds have been made convenient for more universal use by adding lifting and vibrator massage motors controllable by a handheld controller. For example U.S. Pat. No. 5,235,258 entitled REMOTELY CONTROLLED ARTICULATED BED describes an articulated bed manipulated by head and foot motors and vibrated by head and foot vibrator motors which are controlled by a wireless remote unit.
However, there is danger that as more controllable features and options are added to such "automatic" beds they actually may become more difficult and frustrating to use. For example, if head and foot portions of the bed can be put in countless different positions and the head and foot vibrators can be set for a variety of speeds and massage patterns, the user may find it difficult to restore the bed to a favored setting once it has been readjusted for some reason. Moreover, if previously the bed has been left in a chair-like curved position, a tired or distraught person wanting to just lie on the bed in a more conventional position may not be in the mood to "play" with the controls.
It would be highly desirable if there were some way the user could easily make the bed automatically return to a favored "bed setting", without adding greatly to the cost of the bed or complexity in operating it. But any mechanism which causes such a bed to automatically adjust its shape significantly might present a danger to a handicapped, sick or feeble person who inadvertently triggers the mechanism and cannot immediately bring it to a halt. Therefore, such a feature cannot be added without first devising some foolproof way for even a surprised or frightened person to easily halt any such automatic motion.
It is an object of the invention to provide an articulated bed and a method and device for operating it by which the user can customize several favorite settings of the bed's lifting and massaging motors and of even associated equipment, such as a bedlamp or T.V. A further object is to provide a safety mechanism by which even a surprised or frightened person can halt such an automatic adjustment motion of the bed.
SUMMARY OF THE INVENTION
In an articulated bed having a motor for raising and lowering the bed, a control circuit operated by the user has first user memory for storing a first user variable indicating a user-selected first preferred bed position and a recall button by which the user can command that a handler routine in the control circuit return the bed to the first preferred bed position indicated by the first user variable. Further, the control circuit can have a tracking memory for frequently storing a tracking variable indicating the current position of the bed and a "store" or "program" button or control by which the user can command that the first user variable be set to equal the current tracking variable. Thus, any time the bed is in a position preferred by the user, the user can push the store button to store a user variable indicating the preferred bed position in the controller's memory; then afterwards the user can have the bed return to that preferred position by pressing the recall button.
Bed controllers usually have a number of control buttons for controlling different elements and functions of the bed. As a safety feature, whenever the bed is moving automatically in response to the recall button, pressing any button on the handheld controller halts and aborts the recall. Thus, even a user surprised or frightened by the "recall" movement of the bed will be able to halt the bed by pressing any key on the handheld control.
For storing the user's preferred "bed state" sufficient memory is provided for storing all user's preferred settings. For example, on a bed where the head and foot position, head and foot massage speed and pulse mode, and remote and bed-attached electric outlets are all controllable, all their settings are stored by pressing one program key (for example, labeled "p") and one memory location (for example memory key 1); all the settings are recalled just by pressing the same memory location key (for example, memory key 1).





BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a simplified mechanical diagram showing a right side elevation of an embodiment of an articulated, motor-driven bed according to the invention.
FIG. 2 is a block diagram of an embodiment of a handheld, wireless remote control transmitter unit for controlling the bed of FIG. 1.
FIG. 3 is a block diagram of an embodiment of a remote control receiver unit according to the invention, mounted on the bed of FIG. 1 for receiving wireless control signals from the remote control transmitter of FIG. 2.
FIG. 4 is a face view of the handheld remote control transmitter unit of FIG. 2 showing the labeled control buttons.
FIG. 5 is a more detailed, right rear perspective view of the motor-driven articulated bed of FIG. 1, showing how the remote control receiver of FIG. 2 and an auxiliary box can be mounted on the bed.
FIG. 6 is a detailed block diagram of a bed controller unit shown in the remote control receiver unit of FIG. 3
FIG. 7 is a flow chart of a control program for a microcomputer in the bed controller unit of FIG. 6.
FIG. 8 is front elevation of the bed-mounted auxiliary box of FIG. 5.
FIG. 9 is block diagram of a controllable remote Alarm/Auxiliary Receptacle box according to the invention which is controlled by radio signals transmitted from the bed along the internal AC wires of the building.





DETAILED DESCRIPTION
As shown in the simplified mechanical diagram of FIG. 1, an articulated, motor-driven bed shown generally at 20 has an articulated support plate 21a, 21b, 21c, 21d mounted on a base 22 having wheels or casters 23. Preferably the support plate is covered with a clothcovered foam layer 30 and if desired a flexible mattress 31. The support plate is moved by electrical head and foot lifting motors 24 and 25, which are controlled by wire by an electrical circuit in a control box 26, attached to base 22, which responds to control signals from a handheld control. As will be seen below, the handheld control itself can be coupled to control box 26 by a wireless (radio or infrared) link.
An auxiliary box 27 having AC power sockets also controllable (ON/OFF, lamp dimming) by the handheld control for appliances, can also be wired to control box 26 and attached to bed base 22. Electrical head and foot vibrators (massage motors) 28, 29 are respectively mounted on head (21a)and foot (21d) portions of the support plate can also be wired to control box 26 to regulate their ON/OFF times, speed, and pulse operation in response to user choices with the handheld control.
The handheld, wireless remote control transmitter unit shown generally at 32 in FIG. 2 can be used to control the bed's lifting motors 24, 25 and vibration motors 28, 29 and auxiliary box 27 via control box 26. Transmitter unit 32 has a keypad 34 (also see FIG. 4) which the person controlling the bed, typically the person on the bed or nurse, presses to generate electrical motor, vibrator, and auxiliary function command signals for bed control box 26. The command signals are input in parallel to a key message encoder 35 which incorporates a bed address (A, B, C) selected with switch 37a so each bed will only respond to its own corresponding transmitter. As will be seen below, the control box 26 on bed 20 also has an A, B, C address switch can be set to match the address of its corresponding transmitter.
Encoder 35 can be a Motorola MC145026 encoder chip, in which case input lines from the keypad 34 are not simple binary, but can have one of three DC signal voltage states (High Voltage (H), Low Voltage (L), or Open Circuit (0)). As shown in Charts 2A-2C, encoder 35 generates a unique nine-digit key code of H's, L's and O's corresponding to each key pressed. A bed with an "A" address can be programmed to recognize that only encoded key command signals from an Address A transmitter never have a Low (L) signal in lines 1 and 2. A bed with a "B" address can be programmed to recognize that an Address B transmitter always sends a Low (L) signal on line 1, whereas an Address C bed should look for the Low (L) signals an Address C transmitter puts on line 2.
Encoder 35 sends the encoded signals as a serial signal 40 to AM transmitter 39, which can be a conventional radio transmitter (for example, at 300 MHz) with antenna 41 or a conventional infrared transmitter 42.
CHART 1__________________________________________________________________________KEY COMMAND SCHEME KEYKEY NAME # VARIABLE AFFECTED KEY EVENT COMMAND__________________________________________________________________________TIMER K1 TIME.sub.-- REMAINING PRESS DOWN START MASSAGE (IF OFF) STOP MASSAGE (IF ON)HEAD PULSE K2 Cur.sub.-- Head.sub.-- Massage.sub.-- Pulse.sub.-- Mode PRESS DOWN FAST.fwdarw.MEDIUM.fwdarw.SLOW .fwdarw.NO.sub.-- PULSEFOOT PULSE K3 Cur.sub.-- Foot.sub.-- Massage.sub.-- Pulse.sub.-- Mode PRESS DOWN FAST.fwdarw.MEDIUM.fwdarw.SLOW .fwdarw.NO.sub.-- PULSEMEMORY 1 K4 1ST.sub.-- BED.sub.-- STATE PRESS DOWN STORE (Memory Data Structure) (Prog) CURRENT.sub.-- BED.sub.-- STATE PRESS DOWN RECALL (Recall) 1ST.sub.-- BED.sub.-- STATEAUX A K5 Cur.sub.-- Remote.sub.-- Alarm PRESS DOWN REMOTE ALARM ON/(ALARM) REMOTE APPLIANCE ONHD K6 Cur.sub.-- Head.sub.-- Massage.sub.-- Speed PRESS DOWN SPEED: HIGH.fwdarw.LOWMASSAGE .fwdarw.MEDIUMSETHD K7 Cur.sub.-- Head.sub.-- Massage.sub.-- Off PRESS DOWN HEAD MASSAGE OFFMASSAGEOFFPROGRAM K8 Program.sub.-- Mode PRESS DOWN ENTER PROGRAM MODEMEMORY 2 K9 2ND.sub.-- BED.sub.-- STATE PRESS DOWN STORE (Memory Data Structure) (Prog) CURRENT.sub.-- BED.sub.-- STATE PRESS DOWN RECALL (Recall) 2ND.sub.-- BED.sub.-- STATEFT MASSAGE K10 Cur.sub.-- Foot.sub.-- Massage.sub.-- Speed PRESS DOWN SPEED: HIGH.fwdarw.LOWSET .fwdarw.MEDIUMFT MASSAGE K11 Cur.sub.-- Foot.sub.-- Massage.sub.-- Off PRESS DOWN FOOT MASSAGE OFFOFFRESET K13 Reset.sub.-- Mode PRESS DOWN HEAD & FOOT TO LEVEL, MASSAGE MOTORS OFFMEMORY 3 K14 3RD.sub.-- BED.sub.-- STATE PRESS DOWN STORE (Memory Data Structure) (Prog) CURRENT.sub.-- BED.sub.-- STATE PRESS DOWN RECALL (Recall) 3RD.sub.-- BED.sub.-- STATEAUX C K15 Cur.sub.-- C.sub.-- Dimmer PRESS DOWN AUX OUTLET C:(DIMMER) ON.fwdarw.DIM.fwdarw.DIMMER .fwdarw.DIMMESTHEAD UP K16 Cur.sub.-- Head.sub.-- Position PRESS DOWN HEAD MOTOR UPHEAD DOWN K17 Cur.sub.-- Head.sub.-- Position PRESS DOWN HEAD MOTOR DOWNFOOT UP K18 Cur.sub.-- Foot.sub.-- Position PRESS DOWN FOOT MOTOR UPFOOT DOWN K19 Cur.sub.-- Foot.sub.-- Position PRESS DOWN FOOT MOTOR DOWNAUX B K10 Cur.sub.-- Aux.sub.-- On PRESS DOWN AUX OUTLET B ON(ON/OFF)__________________________________________________________________________
CHART 2A__________________________________________________________________________KEY CODES FOR ADDRESS A KEY CODE KEY LINE LINE LINE LINE LINE LINE LINE LINE LINEKEY NAME # 1 2 3 4 5 6 7 8 9__________________________________________________________________________TIMER 1 H O O O O H O O OHEAD PULSE 2 O H O O O H O O OFOOT PULSE 3 O O H O O H O O OMEMORY 1 4 O O O H O H O O OAUX A (ALARM) 5 O O O O H H O O OHD MASSAGE SET 6 H O O O O O H O OHD MASSAGE OFF 7 O H O O O O H O OPROGRAM 8 O O H O O O H O OMEMORY 2 9 O O O H O O H O OFT MASSAGE SET 10 H O O O O O O H OFT MASSAGE OFF 11 O H O O O O O H ORESET 13 O O H O O O O H OMEMORY 3 14 O O O H O O O H OAUX C (DIMMER) 15 O O O O H O O H OHEAD UP 16 H O O O O O O O HHEAD DOWN 17 O H O O O O O O HFOOT UP 18 O O H O O O O O HFOOT DOWN 19 O O O H O O O O HAUX B (ON/OFF) 10 O O O O H O O O H__________________________________________________________________________
CHART 2B__________________________________________________________________________KEY CODES FOR ADDRESS B KEY CODE KEY LINE LINE LINE LINE LINE LINE LINE LINE LINEKEY NAME # 1 2 3 4 5 6 7 8 9__________________________________________________________________________TIMER 1 L O O O O H O O OHEAD PULSE 2 L H O O O H O O OFOOT PULSE 3 L O H O O H O O OMEMORY 1 4 L O O H O H O O OAUX A (ALARM) 5 L O O O H H O O OHD MASSAGE SET 6 L O O O O O H O OHD MASSAGE OFF 7 L H O O O O H O OPROGRAM 8 L O H O O O H O OMEMORY 2 9 L O O H O O H O OFT MASSAGE SET 10 L O O O O O O H OFT MASSAGE OFF 11 L H O O O O O H ORESET 13 L O H O O O O H OMEMORY 3 14 L O O H O O O H OAUX C (DIMMER) 15 L O O O H O O H OHEAD UP 16 L O O O O O O O HHEAD DOWN 17 L H O O O O O O HFOOT UP 18 L O H O O O O O HFOOT DOWN 19 L O O H O O O O HAUX B (ON/OFF) 10 L O O O H O O O H__________________________________________________________________________
CHART 2C__________________________________________________________________________KEY CODES FOR ADDRESS C KEY CODE KEY LINE LINE LINE LINE LINE LINE LINE LINE LINEKEY NAME # 1 2 3 4 5 6 7 8 9__________________________________________________________________________TIMER 1 H L O O O H O O OHEAD PULSE 2 O L O O O H O O OFOOT PULSE 3 O L H O O H O O OMEMORY 1 4 O L O H O H O O OAUX A (ALARM) 5 O L O O H H O O OHD MASSAGE SET 6 H L O O O O H O OHD MASSAGE OFF 7 O L O O O O H O OPROGRAM 8 O L H O O O H O OMEMORY 2 9 O L O H O O H O OFT MASSAGE SET 10 H L O O O O O H OFT MASSAGE OFF 11 O L O O O O O H ORESET 13 O L H O O O O H OMEMORY 3 14 O L O H O O O H OAUX C (DIMMER) 15 O L O O H O O H OHEAD UP 16 H L O O O O O O HHEAD DOWN 17 O L O O O O O O HFOOT UP 18 O L H O O O O O HFOOT DOWN 19 O L O H O O O O HAUX B (ON/OFF) 10 O L O O H O O O H__________________________________________________________________________
As shown in FIG. 3, the control box 26 of FIG. 1.has a corresponding AM radio or an infrared receiver 43 using a receiving antenna 44 or infrared-detecting diode 46. Receiver 43 demodulates the received command signals and passes them as a serial signal to a bed controller unit 50 which has a key message decoder 48 followed by a bed controller circuit 52. Key message decoder 48 on bed 20 is set to match the corresponding transmitter for A, B, or C bed addresses by an ABC switch 48a. The decoded key commands are input to bed controller circuit 52, which includes driver circuits (see FIG. 6) which enable the key commands to control head and foot motors 24, 25, head and foot vibrator motors 28, 29, and bed auxiliary box 27. Bed auxiliary box 27 can include a low frequency remote AM radio transmitter 58 (for example having a ten KHz carrier) which can pass control signals using the building electrical wiring 62 to a remote receptacle 60 plugged into an electrical socket elsewhere in the building in which the bed is placed.
As shown in FIG. 4, handheld remote control transmitter 32 unit having a power indicator light 32a has a number of specially labeled keys whose functions are summarized in Chart 1. The user can press a key to have the head motor raise (K16) or lower (K17) the head 21a portion of the bed, --to have the foot motor raise (K18) or lower (K19) the foot portion 21d of the bed. A key (K1) labeled "T" for "timer" starts a thirty minute timer for the head and foot vibrator motors 28, 29, either of which can be shut off before the thirty minute interval ends by a corresponding OFF key (K7, K11). By successively pressing head and foot vibrator MASSAGE SET keys (K6, K10) the speed of the head and foot vibrator motors 28, 29 can be changed in the order HIGH, LOW and MEDIUM.
When vibrator motors 28, 29 are running, they can be shifted between preset pulse rhythms by successively pressing HEAD and FOOT MASSAGE PULSE keys (K2, K3). The available pulse rhythms are NORMAL (no pulsing) or pulsed intervals: FAST (two seconds ON, two seconds OFF), MEDIUM (four seconds ON, four seconds OFF), SLOW (six seconds ON, six seconds OFF).
A bed RESET key (K13) makes head and foot motors 24, 25 return the bed to level and shuts off vibrator motors 28, 29.
Another view of how control box 26 can be mounted under the bed is shown in FIG. 5. Auxiliary box 27, which is attached at the rear of base 22, has its own AC power cord 64 and a low voltage control signal line 66 which plugs into a modular jack 26a on control box 26 to receive decoded key commands sent from handheld transmitter unit 32. As can be seen better in the block diagram of FIG. 9, auxiliary box 27 has an AC outlet 68 for an appliance and an AC outlet 70 which includes a dimmer for a lamp, both of which are controllable by the decoded key commands. An auxiliary ABC code switch 72 and reset button 74 are also provided as shown in FIG. 5.
FIG. 6 shows the computerized bed controller unit 50 which includes a programmed Intel LM80C22 microcomputer 80, which is similar to the Intel 8051 microcomputer. Microcomputer 80 has on board Read Only Memory (PROGRAM ROM) 82 for storing a control program (see FIG. 7) and a scratchpad read/write random access memory (SCRATCHPAD RAM) 84 for storing variables and scratchpad calculations. It also has an on-board timer 86, useful for measuring the thirty minute run time for the vibrator motors 28, 29.
At terminal 89 Bed Address Selector 48a provides microcomputer 80 a bed address selection (A, B, or C) set the same as the corresponding handheld transmitter's Bed Address. The received, demodulated encoded key messages are input on line 49 from receiver 43 to microcomputer terminal 88. Microcomputer 80 decodes the key command messages from the user and then at terminals 90, 91, 92, 93 sends appropriate digital control signals to driver circuits 94, 96, 98, 100 to control the head and foot motors 24, 25, head and foot vibrators 28, 29 and bed auxiliary box 27 to carry out the key commands.
FIG. 7 shows a flowchart of the controller program for microcomputer 80. At P2 the bed address of a key message is read and if at P3 the address does not match that of the microcomputer the program loops back to P2 for the next message. If the bed address is correct at P3, at P4 a check is made to determine if the microcomputer is currently executing a memory recall. If it is, regardless of the key press the microcomputer performs an emergency stop at P5, and then loops back for the next message. If a memory recall is not in progress, the microcomputer decodes the key command at P6 and then depending on the decoded command switches to an appropriate handler routine for the motors (P7), vibrators (P8), memory keys (P9), auxiliary units (P10), and bed reset function (P11). After the appropriate handler routine finishes the program loops back to P2 for the next key message.
CHART 3__________________________________________________________________________MEMORY DATA STRUCTURES__________________________________________________________________________CURRENT.sub.-- BED.sub.-- STATE: M1 1ST.sub.-- BED.sub.-- STATE: M2Cur.sub.-- Head.sub.-- Position 1st.sub.-- Head.sub.-- PositionCur.sub.-- Foot.sub.-- Position 1st.sub.-- Foot.sub.-- PositionCur.sub.-- Head.sub.-- Massage.sub.-- Off 1st.sub.-- Head.sub.-- Massage.sub.-- OffCur.sub.-- Foot.sub.-- Massage.sub.-- Off 1st.sub.-- Foot.sub.-- Massage.sub.-- OffCur.sub.-- Head.sub.-- Massage.sub.-- Speed 1st.sub.-- Head.sub.-- Massage.sub.-- SpeedCur.sub.-- Foot.sub.-- Massage.sub.-- Speed 1st.sub.-- Foot.sub.-- Massage.sub.-- SpeedCur.sub.-- Head.sub.-- Massage.sub.-- Pulse.sub.-- Mode 1st.sub.-- Head.sub.-- Massage.sub.-- Pulse.sub.-- ModeCur.sub.-- Foot.sub.-- Massage.sub.-- Pulse.sub.-- Mode 1st.sub.-- Foot.sub.-- Massage.sub.-- Pulse.sub.-- ModeCur.sub.-- A.sub.-- Remote.sub.-- Alarm 1st.sub.-- A.sub.-- Remote.sub.-- AlarmCur.sub.-- B.sub.-- Aux.sub.-- On 1st.sub.-- B.sub.-- Aux.sub.-- OnCur.sub.-- C-Dimmer 1st.sub.-- C-Dimmer2ND.sub.-- BED.sub.-- STATE: M3 3RD.sub.-- BED.sub.-- STATE: M42nd.sub.-- Head.sub.-- Position 3rd.sub.-- Head.sub.-- Position2nd.sub.-- Foot.sub.-- Position 3rd.sub.-- Foot.sub.-- Position2nd.sub.-- Head.sub.-- Massage.sub.-- Off 3rd.sub.-- Head.sub.-- Massage.sub.-- Off2nd.sub.-- Foot.sub.-- Massage.sub.-- Off 3rd.sub.-- Foot.sub.-- Massage.sub.-- Off2nd.sub.-- Head.sub.-- Massage.sub.-- Speed 3rd.sub.-- Head.sub.-- Massage.sub.-- Speed2nd.sub.-- Foot.sub.-- Massage.sub.-- Speed 3rd.sub.-- Foot.sub.-- Massage.sub.-- Speed2nd.sub.-- Head.sub.-- Massage.sub.-- Pulse.sub.-- Mode 3rd.sub.-- Head.sub.-- Massage.sub.-- Pulse.sub.-- Mode2nd.sub.-- Foot.sub.-- Massage.sub.-- Pulse.sub.-- Mode 3rd.sub.-- Foot.sub.-- Massage.sub.-- Pulse.sub.-- Mode2nd.sub.-- A.sub.-- Remote.sub.-- Alarm 3rd.sub.-- A.sub.-- Remote.sub.-- Alarm2nd.sub.-- B.sub.-- Aux.sub.-- On 3rd.sub.-- B.sub.-- Aux.sub.-- On2nd.sub.-- C-Dimmer 3rd.sub.-- C-Dimmer__________________________________________________________________________
As shown in Chart 3 the bed controller unit 50 includes an electronic random access memory (RAM) in which four memory data structures M1-M4 can each store a group of related variables indicating head and foot bed positions, head and foot massage (vibrator) ON/OFF states, speeds and pulse modes, and the states of three auxiliary devices. The RAM in which M1-M4 are stored can be the scratchpad RAM 84 shown on board the microcomputer of FIG. 6. The bed's three auxiliary devices are a remote alarm 60 controlled by the "A" key (K5) of handheld transmitter unit 32, an ON/OFF auxiliary outlet 68 controlled by the "B" key (K10), and a lamp dimmer outlet 70 controlled by the "C" key (K15).
A memory data structure is a collection of related variables stored in memory which, as a group, convey a particular meaning--here the total controllable state of the bed. Each time bed controller unit 50 adjusts the bed position, the vibrator settings, or the states of auxiliary devices 60, 68, 70 it updates memory data structure M1 so that the current values of the variables making up M1 indicate the current controllable state of bed 20 and its auxiliary devices.
When the user of handheld transmitter unit 32 presses its program key P (K8) followed by its "1" memory key (K4), bed controller unit 50 responds by setting the values of memory structure M2 equal to the current values of structure M1. Thus M2 preserves a first bed state which can later be recalled simply by pressing the "1" memory key (K4) to control the bed back to that state when the user presses the "1" memory key again. The "2"(K9) and "3"(K14) memory keys work in a similar manner to store second and third Bed States for recall later.
As a safety feature, whenever any of the memory keys, "1", "2" or "3" has been pressed to recall a previous bed state, pressing any button on handheld controller halts and aborts the recall. Thus, even a user surprised or frightened by the "recall" movement of the bed can easily halt the bed without a special STOP or EMERGENCY key.
FIG. 8 is a front elevation of the bed-mounted auxiliary box 27 of FIG. 5. It shows bed address switch A-B-C 72, AC outlet 68, AC outlet 70, AC power cord 64, signal line 66, control module 104, lines 106, 110, and house wire transmitter 108.
FIG. 9 is a block diagram of a controllable remote alarm/auxiliary receptacle box according to the invention which is controlled by radio signals transmitted from the bed along the internal AC wires of the building. It shows AC line voltage in 110, line 112, AM receiver 114, Decoder 116 with alarm 117 (having left and right "on" and "off" positions), A-B-C switch 118, reset 122, and auxiliary AC outlet 124.
While the present invention is described with reference to particular embodiments, those skilled in the art will recognize that many variations may be employed without departing from the spirit and scope of the invention as set forth in the claims. For example, the illustrated embodiments use a wireless handheld remote control transmitter unit 32 but the inventive memory and safety features would still be present if the transmitter were wired to control box 26. Similarly if the bed to be controlled has a different combination of lifting motors, vibrators and auxiliary units, the details of Memory Structures M1-M4 can be correspondingly modified while still employing the claimed invention.
Claims
  • 1. In an articulated bed having a motor for raising and lowering the bed in response to a control circuit remotely operated by a user of the bed, the improvement comprising:
  • a first user memory in the control circuit for storing a first user variable which is remotely communicated to said control circuit to indicate a user-selected first preferred position of the bed;
  • a first recall control by which the user can remotely command that the bed be returned to said first preferred position indicated by said first user variable; and
  • a handler routine in the control circuit responsive to said first recall control for returning the bed to said first preferred position indicated by said first user variable.
  • 2. In the articulated bed of claim 1, the improvement further comprising:
  • a tracking memory in the control circuit for storing a tracking variable as often as needed to indicate a current position of the bed; and
  • a first store control by which the user can command that said first user variable be set to equal a current tracking variable.
  • 3. The articulated bed of claim 1, wherein the control circuit has a plurality of user controls for different functions, and whenever said handler routine is returning the bed to a preferred position in response to said first recall control, pressing any of the user controls halts and aborts said handler routine.
  • 4. In the articulated bed of claim 1, the improvement further comprising:
  • an auxiliary box electrically connected to the control circuit and including at least one controllable AC power socket, said auxiliary box being remotely controllable by the user through the control circuit.
  • 5. The articulated bed of claim 4, wherein said auxiliary box further comprises:
  • a remote transmitter for transmitting control signals via building electrical wiring to a remote receptacle plugged into an electrical socket located adjacent to the bed.
  • 6. The articulated bed of claim 5, wherein said remote transmitter comprises a low frequency remote AM radio transmitter.
  • 7. In an articulated bed having a motor for raising and lowering the bed in response to a control circuit remotely operated by a user of the bed, the improvement comprising:
  • a first tracking memory in the control circuit for storing a first tracking variable as often as needed to indicate a current position of the bed;
  • a first user memory in the control circuit for storing a first user-selected variable;
  • a first store control by which the user can command that said first user-selected variable be set to equal a current first tracking variable;
  • a first recall control by which the user can command that the bed be returned to a first relative position indicated by said first user-selected variable; and
  • a first handler routine in the control circuit responsive to said first store control for returning the bed to said first relative position indicated by said first user-selected variable.
  • 8. In the articulated bed of claim 7, the improvement further comprising:
  • a second user memory in the control circuit for storing a second user-selected variable;
  • a second store control by which the user can command that said second user-selected variable be set to equal a current second tracking variable;
  • a second recall control by which the user can command that the bed be returned to a second relative position indicated by said second user-selected variable; and
  • a second handler routine in the control circuit responsive to said second store control for returning the bed to said second relative position indicated by said second user-selected variable.
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