阅读说明：本技术 智能床系统 (Intelligent bed system ) 是由 尼基尔·奥塔尔 尼克·拉贝 于 2019-10-10 设计创作，主要内容包括：本发明涉及智能床系统(100),包括多个不同的可与现有常规床架(102)和/或床垫(104)结合操作或独立于其操作的组成部分。床系统(100)包括可倾斜床设备(200),其被配置成位于现有床架(202)或床垫上,提供患者或使用者的选择性倾斜。传感器垫系统(300)适于位于床垫(104)上。传感器垫系统(300)包括多个不同的层,用于感测患者的姿势和运动。可充气气囊系统(400)包括多个可充气单元,用于选择性地调节使用床系统(100)的患者的姿势或所承受的压力。支撑栏系统(900)支撑床上的使用者。微控制器(600)执行各种与系统(100)相关联的控制和数据处理操作。用于系统(100)的各种控制的用户输入可由遥控器(700)提供,其与微控制器(600)数据通信。(The present invention relates to a smart bed system (100) comprising a plurality of different components that can operate in conjunction with or independently of existing conventional bed frames (102) and/or mattresses (104). The bed system (100) includes a tiltable bed apparatus (200) configured to be positioned on an existing bed frame (202) or mattress, providing selective tilting of a patient or user. The sensor mat system (300) is adapted to be positioned on a mattress (104). The sensor pad system (300) includes a plurality of different layers for sensing the posture and motion of a patient. The inflatable bladder system (400) includes a plurality of inflatable cells for selectively adjusting the posture or pressure experienced by a patient using the bed system (100). The support rail system (900) supports a user in a bed. The microcontroller (600) performs various control and data processing operations associated with the system (100). User input for various controls of the system (100) may be provided by a remote control (700) in data communication with the microcontroller (600).)

1. A tiltable bed apparatus configured to be positioned on a bed frame, the bed apparatus comprising:

a base for supportingly engaging the bed frame or a mattress thereof;

a support arm hingedly attached to the base and adapted to engage a support base for supporting a user; and

an actuation system configured to selectively rotate the support arm relative to the base between a plurality of predetermined angular positions.

2. The tiltable bed apparatus of claim 1, wherein the base comprises at least one longitudinally extending base member extending at least partially along a length of the bed frame.

3. The tiltable bed apparatus of claim 2, wherein the support arm comprises at least one longitudinally extending support member extending at least partially along a length of the bed frame.

4. The tiltable bed apparatus of claim 3, wherein the base comprises a plurality of longitudinally extending base members extending at least partially along a length of the bed frame.

5. The tiltable bed apparatus of claim 4, wherein the support arm comprises a plurality of longitudinally extending support members extending at least partially along a length of the bed frame.

6. The tiltable bed apparatus of claim 5, wherein the support arm comprises a plurality of substantially planar support panels releasably engageable with the longitudinally extending support members.

7. The tiltable bed apparatus of claim 6, wherein the planar support panel comprises an engagement hole on one side and an engagement protrusion on the other side, the engagement hole being configured to receive a corresponding engagement protrusion on an adjacent support panel.

8. The tiltable bed apparatus of any of claims 4-7, wherein the length of at least a subset of the plurality of longitudinally extending base members is longitudinally adjustable.

9. The tiltable bed apparatus of claim 8, wherein at least a subset of the plurality of longitudinally extending base members are telescopically adjustable in length.

10. The tiltable bed apparatus of any of claims 4-9, wherein the base comprises three parallel arranged longitudinally extending base members and the support arm comprises three parallel arranged longitudinally extending support members.

11. The tiltable bed apparatus of claim 10, wherein the lengths of the two outer base members are telescopically adjustable.

12. A tiltable bed apparatus as claimed in claim 10 or 11, wherein the actuation system is mounted on a central base member intermediate two outer base members and the actuation system is mechanically connected to the central support member intermediate the two outer support members.

13. The tiltable bed apparatus of any of claims 4-12, wherein the base comprises a transverse base member extending transversely between the plurality of longitudinally extending base members across a width of the bed frame, and the support arm comprises a transverse support member extending transversely between the plurality of longitudinally extending support members across a width of the bed frame.

14. The tiltable bed apparatus of claim 13, wherein the length of the transverse base member and the transverse support member are laterally adjustable.

15. The tiltable bed apparatus of claim 13, wherein the length of the transverse base member and the transverse support member are telescopically adjustable.

16. A tiltable bed apparatus as claimed in any preceding claim, wherein the base is joined to the bed frame by straps.

17. A tiltable bed apparatus as claimed in claim 8, 9 or 11, wherein the two outer base members comprise vertically extending feet for supportingly engaging one end of the support base.

18. The tiltable bed apparatus of claim 17, wherein the support base is a mattress.

19. The tiltable bed apparatus of claim 17, wherein the support base is an air bladder comprising a plurality of individually inflatable cells.

20. The tiltable bed apparatus of claim 19, wherein a plurality of the units are arranged in a transverse direction on a surface of the bed frame.

21. A tiltable bed apparatus as claimed in claim 19 or 20, wherein a plurality of the units are arranged on two or more vertical levels.

22. A tiltable bed apparatus as claimed in any preceding claim, wherein the actuation system comprises an electrically powered linear actuator configured to linearly extend or retract an actuator arm connected between the base and the support arm.

23. An inflatable airbag system, comprising:

a plurality of inflatable cells; and

a gas delivery system for selectively delivering gas from a gas supply to the cell, the gas delivery system comprising:

one or more pumps connected to the gas supply;

a plurality of gas supply lines connected between the one or more pumps and at least a subset of the plurality of inflatable cells;

a plurality of electrically actuated valves disposed on respective ones of the plurality of gas supply lines, responsive to electrical control signals, for selectively opening or closing the valves to deliver gas to the inflatable unit; and

an inflation microcontroller configured to generate the electrical control signal.

24. The inflatable airbag system of claim 23, wherein the plurality of inflatable cells are divided into groups, each group having a respective electrically actuated valve configured to supply gas to each cell within the group along a common gas supply line.

25. The inflatable airbag system of claim 24, wherein at least a subset of the inflatable cells within a group are separated by pressure valves that allow gas to flow from a first cell to a second cell when the first cell reaches a predetermined pressure threshold.

26. The inflatable airbag system of claim 23, wherein each cell comprises a respective electrically actuated valve for receiving gas along a respective gas supply line such that each cell is independently inflatable.

27. The inflatable airbag system of any of claims 23-26, wherein the plurality of inflatable cells are divided into vertically distributed layers.

28. The inflatable airbag system of any of claims 23-27, wherein the plurality of inflatable cells are divided into a two-dimensional horizontal cell array.

29. The inflatable airbag system of claim 28, wherein the plurality of inflatable cells are divided into a three-dimensional cell grid.

30. The inflatable airbag system of any of claims 23-29, wherein the inflation microcontroller is responsive to one or more weight or pressure sensors configured to sense a weight or pressure of an object located on the inflatable cell.

31. The inflatable airbag system of any of claims 23-30, wherein the microprocessor generates the electrical control signal in response to a user input.

32. The inflatable airbag system of any of claims 23-31, wherein the user input comprises a wireless signal received from a remote control device.

33. The inflatable airbag system of any of claims 23-32, wherein the user input comprises a voice command.

34. The inflatable airbag system of any of claims 23-33, wherein the inflation microcontroller deflates all inflatable cells in response to a CPR override signal.

35. The inflatable airbag system of any of claims 23-35, comprising a rigid layer positioned below the plurality of inflatable cells.

36. The inflatable airbag system of any of claims 23-35, wherein at least a subset of the plurality of inflatable cells comprises an internal electrically-sensitive valve or an internal pressure-sensitive valve that allows gas to flow between adjacent cells.

37. The inflatable bladder system of any of claims 23-36, wherein the gas is air.

38. The inflatable airbag system of any of claims 23-37, comprising an engagement strap configured to engage the inflatable airbag system with a mattress or bedframe.

39. A sensor mat system for a bed, the sensor mat system comprising:

a first layer comprising a piezoelectric material surrounded by a plurality of conductive elements configured to generate a first pressure signal in response to an applied pressure;

a second layer comprising a plurality of spatially distributed sensors configured to generate a second pressure signal in response to an applied force; and

a sensor microcontroller in electrical communication with the conductive element and the sensor to process the first pressure signal and the second pressure signal to generate pressure data indicative of a spatial distribution of pressure across the sensor mat.

40. The sensor mat system of claim 39, comprising a gel material positioned between the first layer and the second layer.

41. The sensor mat system according to claim 39 or 40, wherein the sensor comprises one or more of a force sensitive resistor, a strain gauge, a load sensor, a capacitive transducer and/or a tensile sensor.

42. The sensor mat system according to any of claims 39-41, wherein the sensor microcontroller is configured to determine a posture of a subject lying on the sensor mat system based on the pressure data.

43. The sensor mat system according to any of claims 39-42, wherein the sensor microcontroller is configured to determine a movement pattern of a subject lying on the sensor mat system based on the pressure data.

44. The sensor mat system according to any of claims 39-43, wherein the sensor microcontroller is configured to determine a movement pattern of a subject lying on the sensor mat system based on the pressure data.

45. The sensor mat system according to any of claims 39-44, wherein the sensor microcontroller is configured to determine physiological signals of a subject lying on the sensor mat system based on the pressure data.

46. The sensor mat system according to any of claims 39-45, wherein the sensor microcontroller is configured to predict a potential pressure sore of a subject lying on the sensor mat system based on the pressure data.

47. The sensor mat system according to any of claims 39-46, wherein the sensor microcontroller is configured to detect a potential drop event of a subject lying on the sensor mat system based on the pressure data.

48. The sensor mat system according to any of claims 39-47, comprising a third layer comprising one or more embedded humidity sensors.

49. The sensor mat system according to any of claims 39-48, comprising a communication module for transmitting the pressure data to a remote database.

50. The sensor mat system according to any one of claims 39-49, wherein the sensor microcontroller is configured to generate a third party alert based on the pressure data.

51. The sensor mat system according to any of claims 39-50, wherein the sensor microcontroller is configured to transmit the pressure data to an inflation microcontroller of the inflatable airbag system according to any of claims 23-38, and wherein the electrical control signal is based on the pressure data.

52. The sensor mat system according to any of claims 39-51, wherein the sensor microcontroller is configured to receive an electrical control signal from an inflation microcontroller of the inflatable airbag system of any of claims 23-38, and wherein the pressure data is generated based on the received electrical control signal.

53. The sensor mat system according to claim 51 or 52, wherein the sensor microcontroller of the sensor mat system is the same as the inflation microcontroller of the inflatable airbag system.

54. The sensor mat system of claim 45, wherein the physiological signal comprises a heart rate of the subject.

55. The sensor mat system of claim 45, wherein the physiological signal comprises a respiration rate of the subject.

56. The sensor mat system according to claim 45, 54 or 55, wherein the physiological signal is derived by performing a spectral analysis on the pressure data.

57. The sensor mat system according to any of claims 39-56, wherein the microprocessor is adapted to predict a health condition of a subject based on the pressure data.

58. The sensor mat system of claim 57, wherein the health condition comprises sleep apnea.

59. The sensor mat system according to claim 57 or 58, wherein the health condition comprises cardiac arrest.

60. The sensor mat system according to any of claims 57-59, wherein the health condition comprises epilepsy.

61. The sensor mat system according to any of claims 39-60, wherein the second layer comprises one or more of a thermometer and/or a UV sensor.

62. The sensor pad system of any one of claims 39-60, comprising one or more of a camera, a UV detector, or a radar beam generator device.

63. The sensor mat system according to any one of claims 39-62, wherein the sensor microcontroller is configured to connect to a cloud-based system that utilizes a machine learning algorithm to continuously improve alerts for pressure sore detection based on the pressure data.

64. The sensor mat system according to any of claims 39-62, wherein the sensor microcontroller is configured to connect to a cloud-based system that utilizes a machine learning algorithm to continuously improve an alert for drop detection based on the pressure data.

65. The sensor mat system according to any one of claims 39-62, wherein the sensor microcontroller is configured to connect to a cloud-based system that utilizes a machine learning algorithm to continuously improve alerts for adverse conditions associated with lower respiration rates based on the pressure data.

66. The sensor mat system according to any of claims 39-62, wherein the sensor microcontroller is configured to connect to a cloud-based system that utilizes machine learning algorithms to continuously improve alerts for adverse conditions associated with heart rate fluctuations based on the pressure data.

67. The sensor mat system according to any one of claims 39-62, wherein the sensor microcontroller is configured to connect to a cloud-based system that continuously monitors sleep patterns based on the pressure data using a machine learning algorithm.

68. A bed system, comprising:

a tiltable bed apparatus as claimed in any of claims 1 to 22;

the inflatable airbag system of any of claims 23-38; and

the sensor mat system according to any of claims 39-67.

69. The bed system of claim 68, comprising a microphone for receiving voice instructions from a user, and wherein the sensor microcontroller or inflation microcontroller is adapted to perform voice recognition to convert the voice instructions into corresponding control signals for controlling one or both of the actuation system and electrically actuated valve.

70. The bed system as claimed in claim 68 or 69, comprising one or more cover sheets extending over the bed system to secure the system to a bed frame by one or more engagement structures, wherein the one or more cover sheets are capable of being used as a conventional bed sheet for a user.

71. The bed system of any one of claims 68-69, wherein the inflation or sensor microcontroller is in electrical or wireless communication with a remote control device for receiving user input instructions.

72. The bed system of claim 71, wherein the gas-filled or sensor microcontroller controls the actuation system of the tiltable bed apparatus in response to user input commands.

73. The bed system of any one of claims 68-72, comprising a speaker system configured to communicate audio information to a user.

74. The bed system of any one of claims 68-73, comprising one or more electrical ports for connecting and/or charging electronic devices.

75. A support rail system for a bed, the support system comprising:

an engagement structure for engaging with a bed frame;

a support rail mounted on the engagement structure;

one or more support legs extending downwardly from the engagement structure, the support legs being adjustable in length to engage the floor adjacent the bed to retain the support rail in the operable position.

76. A support rail system according to claim 75, wherein the length of the one or more support legs is telescopically adjustable.

77. A support rail system according to claim 76, wherein the length of the one or more support legs is electronically telescopically adjustable in response to a control signal.

78. A support rail system according to any of claims 75-77, wherein the height of the support rail is adjustable.

79. A support rail system according to claim 78, wherein the height of the support rail is telescopically adjustable.

80. A support rail system according to any one of claims 75-79, wherein the support rail is rotatable relative to the engagement structure between the operable position and the collapsed position by means of a hinged joint.

81. The support rail system of claim 80, wherein the support rail is electronically rotatable in response to a control signal.

82. A support rail system according to claim 80 or 81, wherein the support rail extends substantially in a vertical direction in the operable position.

83. A support rail system according to any one of claims 75-82, wherein the engagement structure includes an engagement arm that extends substantially horizontally for positioning under a mattress of a bed.

84. A support rail system according to any one of claims 75-83, wherein the one or more support legs extend downwardly and outwardly from the bed.

85. A support rail system according to any one of claims 75 to 83, comprising two support legs.

86. A support rail system according to any one of claims 75-85, wherein the engagement structure is rotatable between an operable position and a folded position.

87. A mattress for use with the inflatable bladder system of any of claims 23-38, the mattress having a series of cuts or perforations at the bottom at locations corresponding to the plurality of inflatable cells.

Technical Field

The present application relates to bed systems, and in particular to tilting bed devices, inflatable bladder systems, sensor mat systems, support rail systems, and bed systems configured to be positioned on a bed frame.

Embodiments of the present invention are particularly suited for use with patients in a treatment site, such as a hospital or clinic. However, it should be understood that the present invention may be applied in a wider range of environments and other applications, for example, for everyday users in a home location.

Background

Patients in hospitals and treatment settings are often afflicted with various complications, such as falls and bed sores. These are not only frequent events for injured patients, but also for temporarily or permanently disabled persons and socially qualified members. These problems are secondary in nature, in that they are not the primary cause of personal injury, but rather are caused by complications in the human condition or treatment environment. However, they are of prime importance as they occur frequently and cause injury to the patient, prolonged hospital recovery time, and even death.

In addition to the personal difficulties that these complications can cause, they can place additional burdens on the healthcare system, leading to increased medical costs and reduced resources for others requiring care.

Currently, preventable problems such as falls and bed sores are addressed using complex hospital bed systems in conjunction with the regular monitoring of the professional. The equipment required is expensive and maintenance complex. In addition, in the presence of primary or secondary healthcare personnel, it often takes a long time to operate and monitor.

In addition, there are millions of people worldwide with inadequate sleep or insomnia due to a range of diseases. However, currently, monitoring parameters such as movement, breathing and heart rate of a person during sleep is expensive and time consuming and laborious in the case of sleep laboratory studies; in the case of home monitoring or wearable devices, however, it is invasive and inaccurate, and is only an estimate.

Any discussion of the background art throughout the specification should in no way be considered as an admission that such art is widely known or forms part of common general knowledge in the field.

Disclosure of Invention

According to a first aspect of the present invention, there is provided a tiltable bed apparatus configured to be positioned on a bed frame, the bed apparatus comprising:

a base for supportingly engaging the bed frame or a mattress thereof;

a support arm hingedly attached to the base and adapted to engage a support base for supporting a user; and

an actuation system configured to selectively rotate the support arm relative to the base between a plurality of predetermined angular positions.

In some embodiments, the base includes at least one longitudinally extending base member extending at least partially along a length of the bed frame. In some embodiments, the support arm comprises at least one longitudinally extending support member extending at least partially along the length of the bed frame. Preferably, the base comprises a plurality of longitudinally extending base members extending at least partially along the length of the bed frame. Preferably, the support arm comprises a plurality of longitudinally extending support members extending at least partially along the length of the bed frame.

In some embodiments, the support arm includes a plurality of substantially planar support panels releasably engageable with the longitudinally extending support members. In some embodiments, the planar support panel includes an engagement hole on one side and an engagement protrusion on the other side, the engagement hole being configured to receive a corresponding engagement protrusion on an adjacent support panel.

In some embodiments, the length of at least a subset of the plurality of longitudinally extending base members is longitudinally adjustable. In some embodiments, at least a subset of the plurality of longitudinally extending base members are telescopically adjustable in length.

In some embodiments, the base comprises three longitudinally extending base members arranged in parallel and the support arm comprises three longitudinally extending support members arranged in parallel. In some embodiments, the lengths of the two outer base members are telescopically adjustable.

In some embodiments, the actuation system is mounted on a central base member intermediate two outer base members, and the actuation system is mechanically coupled to the central support member intermediate the two outer support members.

In some embodiments, the base includes a lateral base member extending laterally between the plurality of longitudinally extending base members across the width of the bed frame, and the support arm includes a lateral support member extending laterally between the plurality of longitudinally extending support members across the width of the bed frame.

In some embodiments, the length of the lateral base member and the lateral support member is laterally adjustable. Preferably, the length of the lateral base member and the lateral support member are telescopically adjustable.

In some embodiments, the base is engaged with the bed frame by a strap.

In some embodiments, the two outer base members include vertically extending feet for supportingly engaging one end of the support base. In one embodiment, the support substrate is a mattress. In another embodiment, the support substrate is an air bladder comprising a plurality of individually inflatable cells. Preferably, a plurality of the units are arranged in a lateral direction on a surface of the frame. Preferably, a plurality of said cells are arranged on two or more vertical layers.

In some embodiments, the actuation system includes an electric linear actuator configured to linearly extend or retract an actuator arm connected between the base and the support arm.

According to a second aspect of the present invention, there is provided an inflatable airbag system comprising:

a plurality of inflatable cells; and

a gas delivery system for selectively delivering gas from a gas supply to the cell, the gas delivery system comprising:

one or more pumps connected to the gas supply;

a plurality of gas supply lines connected between the one or more pumps and at least a subset of the plurality of inflatable cells;

a plurality of electrically actuated valves disposed on respective ones of the plurality of gas supply lines, responsive to electrical control signals for selectively opening or closing the valves to deliver gas to the inflatable cells; and

an inflation microcontroller configured to generate the electrical control signal.

In some embodiments, the plurality of inflatable cells are divided into groups, each group having a respective electrically actuated valve configured to supply gas to each cell within the group along a common gas supply line. In some embodiments, at least a subset of the inflatable cells within a group are separated by pressure valves that allow gas to flow from a first cell to a second cell when the first cell reaches a predetermined pressure threshold. In some embodiments, each cell includes a respective electrically actuated valve for receiving gas along a respective gas supply line such that each cell is independently inflatable.

In some embodiments, the plurality of inflatable cells are divided into vertically distributed layers. In some embodiments, the plurality of inflatable cells are divided into a two-dimensional horizontal cell array. Preferably, the plurality of inflatable cells is divided into a three-dimensional cell grid.

In some embodiments, the inflation microcontroller is responsive to one or more weight or pressure sensors configured to sense the weight or pressure of an object located on the inflatable cell.

In some embodiments, the microprocessor generates the electrical control signal in response to a user input. The user input may comprise a wireless signal received from a remote control device. The user input may also include voice instructions.

In some embodiments, the inflation microcontroller deflates all inflatable cells in response to a CPR override signal.

In some embodiments, the inflatable airbag system includes a rigid layer located beneath the plurality of inflatable cells.

In some embodiments, at least a subset of the inflatable cells include an internal electrically-sensitive valve or an internal pressure-sensitive valve that allows gas to flow between adjacent cells.

Preferably, the gas is air.

In some embodiments, the inflatable airbag system includes an engagement strap configured to engage the inflatable airbag system with a mattress or a bed frame.

According to a third aspect of the present invention, there is provided a sensor mat system for a bed, the sensor mat system comprising:

a first layer comprising a piezoelectric material surrounded by a plurality of conductive elements configured to generate a first pressure signal in response to an applied pressure;

a second layer comprising a plurality of spatially distributed sensors configured to generate a second pressure signal in response to an applied force; and

a sensor microcontroller in electrical communication with the conductive element and the sensor to process the first pressure signal and the second pressure signal to generate pressure data indicative of a spatial distribution of pressure across the sensor mat.

In some embodiments, the sensor mat system includes a gel material positioned between the first layer and the second layer.

In some embodiments, the plurality of sensors includes one or more of a force sensitive resistor, a strain gauge, a load sensor, a capacitive transducer, and/or a tension sensor.

In some embodiments, the sensor microcontroller is configured to determine a position of a subject lying on the sensor mat system based on the pressure data.

In some embodiments, the sensor microcontroller is configured to determine a movement pattern of a subject lying on the sensor mat system based on the pressure data. In some embodiments, the sensor microcontroller is configured to determine a movement pattern of a subject lying on the sensor mat system based on the pressure data. In some embodiments, the sensor microcontroller is configured to determine a physiological signal of a subject lying on the sensor mat system based on the pressure data. In some embodiments, the sensor microcontroller is configured to predict a potential pressure sore of a subject lying on the sensor mat system based on the pressure data. In some embodiments, the sensor microcontroller is configured to detect a potential drop event of a subject lying on the sensor mat system based on the pressure data.

In some embodiments, the sensor mat system includes a third layer that includes one or more embedded humidity sensors.

In some embodiments, the sensor mat system includes a communication module for transmitting the pressure data to a remote database. In some embodiments, the sensor microcontroller is configured to generate a third party alert based on the pressure data. In some embodiments, the sensor microcontroller is configured to transmit the pressure data to an inflation microcontroller of the inflatable airbag system of the second aspect of the invention, and the electrical control signal is based on the pressure data. In some embodiments, the sensor microcontroller is configured to receive an electrical control signal from an inflation microcontroller of the inflatable airbag system of the second aspect of the invention, and the pressure data is generated based on the received electrical control signal.

In some embodiments, the sensor microcontroller of the sensor pad system is the same as the inflation microcontroller of the inflatable airbag system.

In some embodiments, the physiological signal comprises a heart rate of the subject. In some embodiments, the physiological signal includes a respiration rate of the subject. In some embodiments, the physiological signal is obtained by performing spectral analysis on the pressure data.

In some embodiments, the microprocessor is adapted to predict a health condition of the subject based on the pressure data. The health condition may include sleep apnea. The health condition may also include cardiac arrest. The health condition may also comprise epilepsy.

In some embodiments, the second layer includes one or more of a thermometer and/or an ultraviolet sensor.

In some embodiments, the sensor pad system includes one or more of a camera, a UV detector, or a radar beam generator device.

In some embodiments, the sensor microcontroller is configured to connect to a cloud-based system that utilizes machine learning algorithms to continuously improve alerts for pressure sore detection based on the pressure data.

In some embodiments, the sensor microcontroller is configured to connect to a cloud-based system that utilizes a machine learning algorithm to perform one or more of:

improving the alarm for drop detection continuously based on said pressure data.

Improving alerts for adverse conditions associated with lower breathing rates on a continuous basis based on the pressure data.

Improving alerts for adverse conditions associated with heart rate fluctuations on a continuous basis based on the stress data.

Continuously monitoring sleep patterns based on the pressure data.

According to a fourth aspect of the present invention, there is provided a bed system comprising:

a tiltable bed apparatus according to the first aspect;

an inflatable airbag system according to the second aspect; and

the sensor mat system according to the third aspect.

In some embodiments, the bed system comprises a microphone for receiving voice instructions from a user, and the sensor microcontroller or inflation microcontroller is adapted to perform voice recognition to convert the voice instructions into corresponding control instructions for controlling one or both of the actuation system and electrically actuated valve.

In some embodiments, the bed system comprises one or more cover sheets that extend over the bed system to secure the system to a bed frame via one or more engagement structures, wherein the one or more cover sheets can be used as a conventional bed sheet for a user.

In some embodiments, the inflation or sensor microcontroller is in electrical or wireless communication with a remote control device for receiving user input instructions.

In some embodiments, the gas-filled microcontroller or sensor microcontroller controls the actuation system of the tiltable bed apparatus in response to user input commands.

In some embodiments, the bed system includes a speaker system configured to communicate audio information to a user.

In some embodiments, the bed system comprises one or more electrical ports for connecting and/or charging electronic devices.

According to a fifth aspect of the present invention there is provided a support rail system for a bed, the support system comprising:

an engagement structure for engaging with a bed frame;

a support rail mounted on the engagement structure;

one or more support legs extending downwardly from the engagement structure, the support legs being adjustable in length to engage the floor adjacent the bed to retain the support rail in the operable position.

In some embodiments, the length of the one or more support legs is telescopically adjustable. Preferably, the length of the one or more support legs is electronically telescopically adjustable in response to a control signal.

In some embodiments, the height of the support rail is adjustable. Preferably, the height of the support rail is telescopically adjustable.

In some embodiments, the support rail is rotatable relative to the engagement structure between the operable position and the folded position by a hinged joint. Preferably, the support rail is electronically rotatable in response to a control signal. In some embodiments, the support rail extends in a substantially vertical direction in the operable position.

In some embodiments, the engagement structure comprises an engagement arm extending substantially horizontally to be positioned under a mattress of a bed.

In some embodiments, the one or more support legs extend downwardly and outwardly from the bed. Preferably, the support rail system comprises two support legs.

In some embodiments, the engagement structure is rotatable between an operable position and a folded position.

According to a sixth aspect of the invention there is provided a mattress for use with the inflatable bladder system of the second aspect, the mattress having a series of cuts or perforations at the base thereof at locations corresponding to the plurality of inflatable cells.

Brief description of the drawings

Exemplary embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

FIG. 1 is an exploded view of a smart bed system comprising multiple interoperating or independent components;

FIG. 2 is an exploded perspective view of a bed with a tiltable bed apparatus located between a bed frame and a mattress;

FIG. 3 is a perspective view of the tiltable bed apparatus shown in FIG. 2 mounted in an operative position between the bed frame and the mattress;

FIG. 4 is a perspective view of the tiltable bed apparatus shown in FIGS. 2 and 3 mounted in an operative position between the bed frame and the mattress;

FIG. 5 is a front view of the tiltable bed apparatus shown in FIGS. 2-4 shown in a partially tilted position;

FIG. 6 is a side view of the tiltable bed apparatus in a partially tilted position as shown in FIG. 5;

FIG. 7 is a bottom view of the tiltable bed apparatus in a partially tilted position as shown in FIGS. 5 and 6;

FIG. 8 is a perspective view of the tiltable bed apparatus in a partially tilted position as shown in FIGS. 5-7;

FIG. 9 is an alternative perspective view of the tiltable bed apparatus in a partially tilted position as shown in FIGS. 5-8, showing an enlarged inset of the actuation system;

FIG. 10 is an exploded view of the tiltable bed apparatus, with the inset showing the joints of the actuation system;

FIG. 11 is a perspective view of the tiltable bed apparatus in an almost fully tilted position showing an enlarged inset of the articulation joint;

FIG. 12A is a front view of the socket of the articulation joint shown in FIG. 11;

FIG. 12B is a perspective view of the carriage shown in FIG. 12A;

FIG. 13 is a perspective view of the tiltable bed apparatus showing the telescoping arms in extended positions extending from the base member;

FIG. 14 is a perspective view of the tiltable bed apparatus showing the lateral adjustability of the lateral base member and lateral support members to adjust the apparatus width;

FIG. 15 is a plan view of the tiltable bed apparatus showing lateral adjustability of the lateral base member and lateral support members to adjust the apparatus width;

fig. 16 is an exploded view of a sensor mat system for use in the smart bed system of fig. 1;

FIG. 17 is a cross-sectional view of the sensor mat system shown in FIG. 16, illustrating a grid structure of conductive elements extending across the layer of piezoelectric material;

FIG. 18 is a side perspective view of the sensor mat system shown in FIGS. 16 and 17, illustrating the different layers of the system;

FIG. 19 shows a plan view of two sub-layers of conductive elements extending in a vertical array, the two sub-layers forming part of the sensor pad system shown in FIGS. 16-18;

FIG. 20 is a plan view of a pressure sensor layer of the sensor mat system shown in FIGS. 16-19 with an array of sensors embedded therein;

FIG. 21 is a perspective view of an inflatable bladder system for use in the smart bed system of FIG. 1;

FIG. 22 is a cross-sectional view of the inflatable airbag system of FIG. 21, showing the gas delivery system;

FIG. 23 is a perspective view of an alternative tiltable bed apparatus having a plurality of removable support panels;

FIG. 24 is a perspective view of the tiltable bed apparatus as shown in FIG. 23 in a deployed state, in which the apparatus is mounted with additional support panels;

FIG. 25 is a perspective view of a support rail system for a bed;

FIG. 26 is a front view of the support rail system shown in FIG. 25;

fig. 27 is a side view of the support rail system of fig. 25 and 26 in an operative position between the bed frame and the mattress;

FIG. 28 is a side view of a first exemplary profile of the inflatable airbag system shown in FIGS. 22 and 23;

FIG. 29 is a perspective view of the exemplary profile of FIG. 28;

FIG. 30 is a side view of a second exemplary profile of the inflatable airbag system shown in FIGS. 22 and 23;

FIG. 31 is a perspective view of the exemplary profile of FIG. 30;

FIG. 32 is a side view of the first exemplary profile shown in FIGS. 28 and 29 illustrating exemplary dimensions; and

FIG. 33 is a plan view of the inflatable airbag system shown in FIGS. 22 and 23 illustrating exemplary dimensions of the inflatable cells or groups of cells.

Detailed Description

Referring first to fig. 1, an exploded view of a smart bed system 100 is shown. The bed system 100 includes a number of different components that may operate with or independent of existing conventional bed frames 102 and/or mattresses 104. The bed system 100 will be described herein with reference to a retrofit system for a bed in a treatment facility, such as a hospital, clinic, nursing home, or other care facility. Thus, the user of the system 100 will be referred to herein as a "patient". However, it should be understood that the bed system 100 may have broader application, for example, for use by everyday consumers in a home environment. Thus, more generally, a patient may be referred to simply as a "user (or user)" of the system.

The bed system 100 includes a tiltable bed apparatus 200 (shown in fig. 2-15) configured to be positioned on an existing bed frame 102 or mattress to provide selective tilting/reclining of a patient or user. The tiltable bed apparatus 200 is adapted to support a mattress 104 or other support structure for supporting a patient/user in a desired position. Fig. 23 and 24 illustrate a tiltable bed apparatus 800 in an alternative embodiment.

The bed system 100 also includes a sensor mat system 300 (shown in fig. 16-20) that is adapted to be positioned on the mattress 104. The sensor pad system 300 includes a plurality of different layers (as described below) for sensing the posture and motion of the patient.

The bed system 100 also includes an inflatable bladder system 400 (shown in fig. 21 and 22) having a plurality of inflatable cells for selectively adjusting the posture or pressure experienced by a patient/user using the bed system 100.

The bed system 100 also includes a support system 900 (shown in fig. 25-27) for supporting a user in the bed.

Finally, system 100 includes a microcontroller 600 for performing various control and data processing operations associated with system 100, as described below. User input for various controls of the system 100 may be provided by a remote control 700, the remote control 700 being in data communication with the microcontroller 600.

Next, the respective components of the bed system 100 will be explained.

Tiltable bed apparatus

Referring to fig. 2-15, various views of a tiltable bed apparatus 200 are shown. As shown in fig. 2-4, the device 200 is configured to be positioned on the bedframe 102 beneath the mattress 104. The device 200 is largely invisible when installed in an operative position between the bedframe 102 and the mattress 104, as shown in fig. 4.

Referring to fig. 5-9, the apparatus 200 includes a base 202 for supportingly engaging the bed frame 102 or a mattress thereof. The bed frame 102 may be a conventional bed or an adjustable bed, such as a hospital bed. The support arm 204 is hingedly attached to the base 202 by a hinged connection, described below, adapted to engage a support substrate for supporting a user, such as the mattress 104 or an air bag system (as described below). The base 202 includes three parallel disposed longitudinally extending base members 206, 207 and 208 that extend along at least a portion of the bed frame length when the apparatus 200 is installed. Similarly, the support arm 204 includes three longitudinally extending support members 210, 211, and 212 arranged in parallel. The support members 210 and 212 and the base members 206 and 208 are substantially evenly spaced apart across the lateral dimension of the bed frame. The support members 210 and 212 are located at positions corresponding to the base members 206 and 208 in the lateral dimension.

In other embodiments, the base 202 and/or support arm 204 comprise at least one base member, and may comprise a number (e.g., 10) of longitudinally extending members in the form of slats. In one embodiment, the base 202 and/or support arm 204 are formed from a single member that is substantially planar and extends across at least half of the width of the associated bed frame. In other embodiments, the base 202 and/or the support arm 204 may include a plurality of angled cross members or other similar support structures.

The base 202 includes a transverse base member 214 that extends transversely across the entire width of the bed frame between the base members 206 and 208. Similarly, the support arm 204 includes a lateral support member 216 that extends laterally across the entire width of the frame between the support members 210 and 212. The transverse base member 214 may be secured to the longitudinally extending base members 206 and 208 by screws, bolts, spot welds, rivets or other fastening means or means. Similarly, the lateral support member 216 may be secured to the longitudinally extending support members 210 and 212 by screws, bolts, spot welds, rivets or other fastening means or means.

In other embodiments, the base 202 and/or support arm 204 may include a plurality of laterally extending members, such as rods or slats, that connect or abut the longitudinally extending members at different points.

Referring now to fig. 23 and 24, an alternative embodiment tiltable bed apparatus 800 is illustrated. Corresponding features in the device 200 are denoted by the same reference numerals in the device 800. In this embodiment, the support arm 204 includes a plurality of substantially planar support panels 802 and 804 that releasably engage the longitudinally extending support members and the transverse support members 216. In the apparatus 800, another lateral support member 808 is included that extends between the support arm 204 and the base 202. The support panels 802 and 804 can be slidably inserted into the C-channel grooves or other guide structures of the cross members 216 and 808, wherein the cross members 216 and 808 serve as a frame for the panels 802 and 804. As shown in fig. 24, the planar support panel 802-804 includes an engagement hole (not shown) on one side and an engagement protrusion (e.g., 810) on the other side. The engagement holes are positioned and configured to receive corresponding engagement projections of adjacent support panels when slidably engaged with each other, as shown in the inset of fig. 24. Similarly, the longitudinal member 210 and 212 includes an engagement hole (e.g., 812) for slidably engaging the support panel 802 and 804.

Because the base 202 and support arm 204 may extend laterally, additional support panels (e.g., panel 804) of different widths may be added in a modular fashion to accommodate the adjustable width of the device 800. It should be understood that the size and number of support panels may vary in different embodiments. It should also be understood that in other embodiments, the support panels may engage the cross members 216 and 808 at spaced apart locations along the length of the cross members 216 and 808 in a similar manner as the bed deck.

The support panel may be made of any rigid or semi-rigid material, for example, plastic (e.g., acrylic or PVA), metal, or wood. In operation, the support panel 802 and 804 provide additional support for a mattress or other support substrate placed on the device 800 to better support a user.

As shown in fig. 9, the apparatus 200 includes an actuation system 218 configured to selectively rotate the support arm 204 relative to the base 202 between a plurality of predetermined angular positions to support a user at different oblique angles on the bed. Preferably, the actuation system 218 is configured to support the user over an angular range of 0 degrees (corresponding to a prone or supine position) to 90 degrees (corresponding to a sitting position). The actuation system 218 comprises a hydraulic arm 220 mounted at one end to the central base member 207 adjacent to the lateral base member 214 and mechanically connected at its other end to the central support member 211 adjacent to an articulated joint 222 connecting the support member 211 with the base member 207. The hydraulic arm 220 includes a telescoping member whose length is selectively adjustable to angularly tilt the support arm 204 relative to the base 202.

The hydraulic arm 220 is mounted to the base member 207 and the support member 211 by a hinge mechanism as shown in fig. 10. The hydraulic arm 220 is mounted to the base member 207 by a hinge mechanism 226, wherein the hinge mechanism 226 has a protruding flange 228, the flange 228 having a corresponding hole therein for receiving a locking screw 230. Screws 230 protrude through the flange 228 into corresponding holes (not shown) on the hydraulic arm 220 to rotatably secure the hydraulic arm 220 to the base member 207 using a retaining nut (not shown). The hydraulic arm 220 is secured to the support member 211 in a similar manner by a hinge mechanism 232, wherein the hinge mechanism 232 has a pair of identical flanges 234 and 236. Each flange includes a corresponding hole for receiving a locking screw (not shown) to rotatably secure the hydraulic arm 220 to the support member 211 using a locking nut (not shown). Once secured in place, one end 238 of the hydraulic arm 220 abuts the inner surface of the support member 211, providing sufficient force to hold the support arm 204 in the desired tilted position.

In an alternative embodiment, the hydraulic arm 220 may be mounted to the base member 214 and the support member 211 by conventional fastening means or means, such as screws, bolts, spot welds, or rivets.

Figure 10 also illustrates one preferred manner of forming the various components of the base 202 and support arm 204. Specifically, the longitudinal members 206 and 210 and 212 are formed from C-section channel members and the transverse members 214 and 216 are formed from L-shaped members. Each of these components is preferably formed of a rigid, yet lightweight material, such as aluminum alloy 6060. This is a light weight, medium strength heat treatable alloy. The C-section channel design provides additional strength to the longitudinal member (which is the primary load bearing member) to withstand greater weight while reducing the overall weight of the device itself. In other embodiments, more advanced models may use more expensive materials, such as titanium, steel, or carbon fiber. Further, in some embodiments, the members may be formed of a stronger structure, such as a member having a square cross-section.

As shown in fig. 6, 8 and 9, the actuation system 218 further includes an electrically powered linear actuator 224 configured or used to linearly extend or retract the hydraulic arm 220 in response to an actuation signal provided by an associated microcontroller 600 (see fig. 1). The actuation signal may comprise one of a series of voltage signals that cause the linear actuator 224 to move the hydraulic arm 220 between a plurality of predetermined positions to tilt the support arm 204 relative to the base 202 in one of a plurality of angular positions. The stroke length of the linear actuator 224 is designed to raise the user to a maximum height of 90 degrees. The 90 degree tilt is particularly important because it allows a stroke patient to eat without choking or choking.

In some embodiments, the actuation system 218 includes an automatic strength spring (not shown) attached behind the linear actuator 224. This spring serves to control the release of the linear actuator 224 in the event of emergency power shut down, while minimizing force by more effectively translating the leverage of the device into motion. In other embodiments, a different type of electromechanical actuator may be used in place of the linear actuator 224.

Referring now to fig. 11 and 12, the articulation joint 222 is shown in detail. The articulation joint includes a socket 240 having a generally circular bore 242 for receiving a corresponding articulation pin 244, wherein the articulation pin 244 extends between the C-section channels of the support member 211. As shown in the inset in fig. 11, the mount 240 is mounted within the C-section channel of the base member 207, partially transferring the weight of the support member 211 and the associated load on the support arm 204, while facilitating rotational movement of the support member 211. Similar hinged joints are located between base member 206 and support member 210 and between base member 208 and support member 212.

Referring now to fig. 13, to accommodate mattresses (or other support substrates) of varying lengths, the length of the base members 206 and 208 may be adjusted longitudinally, including the respective extension arms 246 and 248. Extension arms 246 and 248 are telescopically extendable along the length of members 206 and 208 toward the foot of the bedframe. In other embodiments, the length of the base member 207 may also extend telescopically.

As shown in panel A of FIG. 13, the extension arms 246 and 248 include a similar C-section channel configuration, but with a slightly wider channel, thereby being able to telescopically fit around the base members 206 and 208. The internal locking mechanism 253 can actuate a downwardly extending locking pin (not shown) into one of a plurality of longitudinally spaced locking holes (not shown) on the extension arm 246 to lock the extension arm 246 in a particular longitudinal position. A similar locking mechanism exists for the extension arm 248. In other embodiments, the locking mechanism 253 includes a snap lock or other type of locking or latching device.

As shown in panel B of FIG. 13, the extension arms 246 and 248 include feet 250 and 252 that can be rotated upward to abut an end of a mattress (or other support substrate). The feet 250 and 252 are rotatable about respective hinged joints 254 and 256 between a retracted position within the channels of the base members 206 and 208 and an upright operating position (shown in fig. 13). In this operative position, the feet 250 and 252 serve as longitudinal support points for a mattress (or other support substrate) on the support arm 204 of the support apparatus 200.

Referring now to fig. 14 and 15, to accommodate mattresses (or other support substrates) of different widths, the length of the lateral base member 214 and lateral support member 216 may be laterally telescopically adjusted. Specifically, the lateral support member 216 includes intermediate portions 258, 260 that are formed from a C-section channel structure and are adapted to slide laterally within the L-shaped structure of the member 216 to adjust the overall width of the lateral support member 216. As shown, the intermediate portions 258 and 260 include a plurality of longitudinally spaced holes (e.g., 262 and 264) that are alignable with corresponding holes (e.g., 266 and 268) on the remaining portions of the lateral support member 216 and adapted to receive respective locking pins (not shown) to lock the portions in place at a fixed width. A similar adjustment is provided to the lateral base member 202 having a similar middle portion and aperture (not shown).

The tiltable bed apparatus 200 described above can be stored in a compact arrangement: rotating feet 250 and 252 to their retracted positions; the extension arms are nested within the respective base members 206 and 208; the lateral support member and the lateral base member are retracted laterally to their minimum positions; and the support arm 204 rests on the base 202. In this position, the apparatus 200 occupies very little space and can be stored under a bed or in a closet.

In use, the device 200 is first placed on the bed frame or mattress of an existing conventional bed (on top of or under the mattress (as shown in fig. 2)). The lateral length of lateral base member 214 and lateral support member 216 (as shown in fig. 14 and 15) are then adjusted and locked in place to accommodate the width of an existing bed frame or mattress. After the cross member is locked in place, the extending arms 246 and 248 are slid from the base members 206 and 208 and locked, rotating the feet 250 and 252 upward to the operating position. A support substrate, such as a mattress or inflatable bladder system (as described below) or a combination thereof, may then be placed on top of the device 200. The feet 250 and 252 support the mattress or foundation in the longitudinal direction and prevent it from sliding in the longitudinal direction.

Other engagement means may also be included to securely support the device 200 on a bed frame. In one embodiment, one or more adjustable or elastic bands may be engaged with the base 202 and/or the bed frame to secure the device 200 to the bed frame. Preferably, a multi-belt system is provided that attaches the device to any bedframe at multiple points to maximize the transfer of force. The straps are preferably formed of a soft fabric material to minimize patient discomfort. Similarly, engagement means (e.g., straps) may be used to secure the mattress or support base to the apparatus 200.

In another embodiment, a cover sheet with elastic outweighs (elastic outlays), Velcro, or other material may be used to attach the sheet down onto the device 200 by means of suitable hooks and loops attached to the base 202. Such a sheet not only allows the device 200 to be secured to a bed frame, but also makes it simple to replace the sheet.

In yet another embodiment, a mattress adhesive hook may be provided for attaching the apparatus 200 to a mattress positioned thereon. In another embodiment, a custom-made mattress may be produced that is attached to the apparatus 200 by way of built-in hooks.

In operation using a conventional bed, the apparatus 200 may convert the conventional bed into an affordable replacement for an expensive hospital bed. In combination with the other components described below, the apparatus 200 can operate as a smart bed system, overcoming at least some of the problems described above. For example, the device 200 may facilitate a disabled patient to move about.

The linear actuator 224 may be controlled by a microcontroller 600, allowing a user (e.g., a physician, clinician, or patient) to control the tilt angle of the support arm 204. User input may be provided by electrical or wireless signals from remote control 700 or a control panel, or electrical or wireless signals from voice commands received by a microphone and processed by microcontroller 600. For example, the user may provide audible instructions such as "bed up (bedup)", "bed down (bed down)", "bed full up (bed full down)", "bed full down (bed down)" and "stop (stop)". For security purposes, the microcontroller 600 may also allow voice recognition to identify a particular user. In some embodiments, microcontroller 600 communicates wirelessly (via bluetooth, Wi-Fi, etc.) with a user/patient's smartphone, and user input may be provided via a software application to control device 200.

The microcontroller 600 is also capable of providing control signals to the linear actuator 224 based on inputs obtained from sensors in the sensor system described below. The microprocessor 600 may include a communication device for collecting various data from the remote control or associated sensor system and may provide an API through which input may be provided to the linear actuator 224. The communication device may facilitate data communication via one or more of bluetooth, infrared, Wi-Fi, Li-Fi, and various other communication protocols, as well as via a direct connection with device 200.

Microcontroller 600 may also be integrated with an associated data or telephone network to enable voice calls to medical personnel and other parties. The microcontroller 600 may also act as a relay point on the part of the patient to connect to a medical professional or a third party, such as a family member. This may enable other parties, such as family members, to monitor patient status using a dedicated software application via a cell phone, tablet, laptop, or other device.

Microcontroller 600 and linear actuator 224 are powered by an electrical connection (not shown) to a mains power supply and/or a battery module.

Other functions of microcontroller 600 will be described below.

In some embodiments, the linear actuator 224 may be manually overridden and the support arm 204 may be manually tilted via a ratchet-crank or pulley system. This allows manual intervention when power is not applied (e.g., during a power outage) or when the battery is depleted. A manual CPR override may be provided which releases all electronic controls to place the patient in the prone position.

As described below, the tiltable bed apparatus 200 can operate in conjunction with the sensor pad system 300, the inflatable bladder system 400, and the microcontroller 600 to provide the smart bed system 100.

Patient sensor system

Referring now to fig. 16-20, a sensor mat system 300 is shown for detecting the posture and movement of a user on a bed. The sensor mat system 300 is adapted to be positioned directly under a user or under a mattress or other support substrate (such as an inflatable bladder system described below). The sensor pad system 300 may be located on the support arm 204 of the apparatus 200 described above.

As shown in fig. 16, the sensor pad system 300 includes a piezoelectric sensing layer 302, the piezoelectric sensing layer 302 including a piezoelectric material 304, the piezoelectric material 304 being surrounded by a plurality of conductive elements 306 and 308. The piezoelectric sensing layer 302 is made up of three separate sublayers, namely a piezoelectric material 304 and upper and lower conductive elements 306 and 308. In operation, the three sublayers adhere together to form a single layer as shown in FIG. 18. Piezoelectric sensing layer 302 is configured to generate a first pressure signal in response to pressure applied by a user lying on sensor mat system 300.

The system 300 also includes a pressure sensor layer 310 that includes a plurality of spatially distributed sensors (e.g., 312) configured to generate a second pressure signal in response to an applied force. These sensors may be one or more of force sensitive resistors, strain gauges, load sensors, capacitive transducers and/or tensile sensors designed to provide positional input of critical locations and to calibrate the piezoelectric layer. Other sensors, such as one or more of a thermometer, an Ultraviolet (UV) light detector, may be embedded within the sensor layer 310.

As shown in fig. 16, the system 300 also includes a sensor microcontroller 600 in electrical communication with the conductive elements 306 and 308 and the sensor 312 via wires. In an alternative embodiment, the conductive elements 306 and 308 and the sensor 312 are capable of communicating wirelessly with the microcontroller 600.

Microcontroller 600 is configured to receive and process the first and second pressure signals to generate pressure data indicative of the spatial distribution of pressure across the sensor mat. In particular, the microcontroller 600 is configured to determine a posture and a movement pattern of a subject lying on the sensor mat system based on said pressure data. Preferably, microcontroller 600 is capable of generating time-varying pressure data for time-dependent historical analysis, such as patient motion patterns. Based on this, further high-level analysis can be performed, as described below.

Although the microcontroller 600 is described as the same as that described above for device 200, it should be understood that in some embodiments, separate microcontrollers may be used for the different components of smart bed system 100. In some embodiments, a separate computer device may replace microcontroller 600.

The system 300 also includes a gel layer 314 located between the piezoelectric sensing layer 302 and the pressure sensor layer 310 and another gel layer 316 located over the conductive element 308 (adjacent to the mattress or support substrate). These gel layers can increase the transfer and distribution of weight (and stretch) to the sensor and increase user comfort. The gel layer 314 may also be used to transfer locations of the pressure sensor layer 310 that may be concentrated around high-demand areas (e.g., ilium/hip in decubitus areas).

Referring to fig. 16, 17 and 19, the conductive elements 306 and 308 include a plurality of conductive elements such as wires 318 and 320 distributed in a parallel array throughout a non-conductive substrate. In other embodiments, wires 318 and 320 may be replaced by other conductive materials, such as conductive tape, fabric, thread, paint, or ink. Typical spacing between wires is on the order of millimeters or centimeters, and the spacing therebetween may be regular or irregular. The conductive line 318 of the conductive element 306 is disposed across the width of the element 306 in the transverse direction, while the conductive line 320 of the conductive element 308 is disposed along the length of the element 308 in the longitudinal direction. As such, the conductive lines of the two conductive elements 306 and 308 are arranged perpendicular to each other.

The piezoelectric material 304 may comprise any commercially available material having a piezoresistive effect, such as artificial ceramics and some semiconductor materials. Another suitable material is Velostat^TMMaterial, which is a product manufactured by 3M company. Piezoelectric materials have the property that the resistance of the entire piezoelectric material changes based on applied stress or pressure. In particular, their resistance will vary with the application to the materialThe increase in pressure decreases.

Conductive elements 307 and 308 are adhered to both sides of piezoelectric material 304 by a non-conductive adhesive material such as polyvinyl chloride (PVC) or Ethylene Vinyl Acetate (EVA) based polymer material or other tape or glue, respectively. In operation, the mutually perpendicular conductive lines 318 and 320 together define a gate structure; the gate structure may allow for spatial sensing of pressure based on a detected voltage level on the wire when a small current flows through the wire. The current may be provided by the microcontroller 600 or another power supply (e.g., a battery or mains supply).

Referring now to FIG. 20, the sensor layer 310 includes a regular array of pressure sensors 312, which pressure sensors 312 may be one or more of force sensitive resistors, strain gauges, load sensors, capacitive transducers, and/or tensile sensors. The sensor 312 is preferably embedded within a flexible fabric material that defines the size and shape of the layer 310. The flexible fabric material may be formed from a PVC or EVA based polymer material. Although not shown in the figures, each sensor is connected to internal wires embedded within the flexible fabric material in a manner similar to an electric blanket. These internal wires transmit a second pressure signal that is transmitted to microcontroller 600.

The sensors of layer 310 are shown to be located in a small area around the user's iliac/hip region, which is the area of concern for pressure sores. However, it should be understood that sensor layer 310 may include a wider array of sensors distributed more broadly across layer 310, and may incorporate a large number of sensors, for example, 50 or 100 sensors. In addition, layer 301 may include sensors concentrated at a higher density around a particular target area (e.g., the user's shoulder, ilium/hip) and around the edges of layer 310, which may detect a potential drop event. In general, the distribution and density of sensors within layer 310 may vary depending on the particular application and cost requirements.

The use of the piezoelectric sensing layer 302 with the pressure sensor layer 310 can combine the input of the piezoresistive material with the input of the embedded force sensitive resistor(s), etc., to produce a pressure profile of patient movement. This combination of sensor layers provides a more accurate environment for piezoresistive pressure (its stretching force and conductivity change over time). This more context-dependent information can be used to more accurately detect how much force is applied at a particular location and to more accurately predict the user's motion, heart rate, respiration rate, and other physiological inputs (e.g., muscle tone). This combination of layers may also calibrate a piezoresistive layer which may change its reading over time due to stretching, which is inherent to its material properties. The more constant nature of the readings of the sensor layer 310 and the distance between sensors can be used to calibrate the input of the piezoelectric layer 302 over time.

Depending on the exact nature of the particular material used to fabricate the piezoelectric layer 304, the layer may have different degrees of elasticity or elongation.

In addition to the various layers described above, the sensor mat system 300 may also include a series of elastic wires and pulleys, which are used in a coordinated manner similar to a spring balance, for measuring stretch. For example, multiple wires may be looped through multiple holes located on the periphery of the sensor mat system 300 and connected to respective spring scales or strain gauges to measure tension. Coordinated inputs from a number of spring scales may be used to generate or augment patient posture and motion data.

In some embodiments, system 300 includes additional layers including one or more embedded humidity sensors and/or other types of sensors for augmenting pressure data. The humidity sensing layer can detect the presence of sweat or urine, which can alert a third party.

System 300 may also include other devices that are coupled to microcontroller 600 to provide higher level functionality. For example, a combination of microphones, cameras, radar beam generators, UV detectors, thermometers, and other devices combine to provide a comprehensive view of the user of system 300 at any given time. The microphone may be used to detect snoring and other noises (e.g., slurred speech) for monitoring stroke. The UV detector helps to inform the user of the desired sleeping environment.

The combination of pressure data from layers 302 and 310 may provide useful input to allow microprocessor 600 to not only generate a pressure profile of user movements, but also perform various other high-level steps (as described below).

In some embodiments, microcontroller 600 is configured to determine a physiological signal, e.g., a respiration rate or a heart rate, of a subject lying on system 300 based on pressure data received by the sensors. This may be achieved by frequency analysis of the dynamic data set relating to the pressure around the user's lungs and/or heart region. The patient/user's breathing cycle or heart cycle produces regular pressure changes that can be represented as a spectral signature of the pressure data obtained by the system 300. The peak frequency can be separated from these signals to assess the user's breathing rate and heart rate.

Microcontroller 600 may also be configured to predict a potential pressure sore for a user lying on system 300 based on the pressure data. For example, the microprocessor 600 may be preprogrammed with predetermined pressure and time thresholds that trigger potential decubitus events. Event detection may be triggered when a patient applies pressure to a particular location for a particular period of time. Such detection by microcontroller 600 may be based on a data look-up table based on clinical data.

Microcontroller 600 may also be configured to detect a potential drop event for a user lying on the sensor mat system based on the pressure data. When the detected pressure profile of the patient indicates that the patient is lying in a position near the edge of the bed, the microcontroller 600 can be programmed to detect a potential fall event and optionally alert the user or a third party.

In some embodiments, microcontroller 600 includes a communication module (not shown), such as an ethernet interface, Wi-Fi adapter, or bluetooth device, for transmitting pressure data and/or other data to a remote database for further processing. For example, the dynamic pressure profile data may be sent to a cloud database for further processing. The cloud database may also be configured to perform functions such as sending alerts to health care professionals and those concerned with situations such as potential drop events and potential bedsores.

Microcontroller 600 can also be configured to generate a series of different third party alerts based on the pressure data. This may be performed directly by the microcontroller 600 or indirectly (through a software application) through a cloud database and/or an associated software interface on the mobile or computer device. This software interface provides third parties with access not only to aspects of the alarm, but also to pressure data and derived physiological signal data. The software applications and systems may also provide insight into past potential or actual fall events, pressure sores, or user movement patterns. These patterns, particularly during sleep times, may be used by the microprocessor 600 or by an associated remote server accessible through a cloud database to predict sleep apnea and like conditions and determine their response to treatment.

Machine learning may also be employed by microcontroller 600 or an associated cloud server to improve the alarm system and allow medical personnel or caregivers to remotely monitor patients through software applications on mobile devices. The cloud server may also calibrate the readings of the system 300 in a bi-directional manner through machine learning. For example, machine learning algorithms may be employed that take input from the sensor pad system 300, improving the accuracy and personalization of alerts for bed sores, drops, emergency events such as respiratory arrest, and the accuracy and personalization of sleep status and time-varying ergonomic posture recommendations. Suitable machine learning algorithms may include supervised or unsupervised decision trees, random forests, support vector machines, naive bayes classification, linear or logistic regression, or artificial neural networks. The machine learning system may also take input from other devices (e.g., blood pressure monitors) to provide alerts and monitoring for other diseases.

By monitoring the pressure data, prediction of more severe situations, such as epilepsy and cardiac arrest, may be performed locally by the microprocessor 600 or remotely by a cloud server. These more advanced predictions may require a higher density of accurate sensors in the pressure sensor layer 310, particularly focused on the area where it is most needed. For example, more sensors located around the chest help detect heart rate and breathing, more sensors located under the shoulders and/or hips help detect bed sores, and more sensors along the edge of the bed help detect falls. Accordingly, the microcontroller 600 or cloud server may be configured to perform various signal processing functions on the pressure data, such as spectral analysis, data filtering, noise removal, linear regression, and data interpolation.

In addition, a higher level of sensing accuracy may provide insight into sleep quality and may provide input to critical parts such as the neck and head of a patient with sleep apnea. The system 300 may provide the user with insight as to which pillow is better suited for them, detecting common painful areas (e.g., low back painful areas), and restless leg syndrome.

In addition to use in bed, the system 300 may also be used in other applications, such as in vehicle seats for monitoring a truck driver sitting in a single space for extended periods of time.

In some embodiments, microcontroller 600 can selectively actuate device 200 to appropriately tilt support arm 204 in response to pressure data.

Inflatable airbag system

Referring now to fig. 21 and 22, an inflatable airbag system 400 is shown. The air bag system 400 may be used in place of or in conjunction with a standard mattress (either above or below the mattress) and may be used as a stand-alone device or as part of the smart bed system 100 in conjunction with one or both of the device 200 and the system 300. In some embodiments, the air bag system 400 may be incorporated into a mattress.

As shown in fig. 21, the inflatable airbag system 400 includes a plurality of inflatable cells 402 that are divided into three vertically distributed layers 404, 406, and 408. Each layer is divided into a two-dimensional array of horizontal cells to form a three-dimensional grid of inflatable cells. The cells may have a common volume or the volumes may be different. As shown, the head end of the system may be provided with a larger sized unit (e.g., 405) to provide additional head support. The housing of the balloon and the inflatable unit 402 are preferably formed of a flexible polymeric material, such as polyurethane, polyvinyl chloride (PVC), polyvinyl alcohol (PVA), or Ethylenediamine (EDA) based polymers. The outer layer of the inflatable airbag system 400 may also include fabric or other materials for providing user comfort. Different comfort models may be made of different materials.

It should be understood that the specific number of inflatable cells may vary, and in other embodiments, a fewer or greater number of layers may be included, or a fewer or greater number of cells may be included in each layer. For example, the number of inflatable cells may be 16-300.

The system 400 further includes a gas delivery system 410, as shown in FIG. 22, for selectively delivering gas from a gas supply 412 to the inflatable cells 402. The gas supply system 410 includes a pump 414 connected to a gas supply 412 for delivering the gas to a plurality of gas supply lines (e.g., 416). In the embodiment shown in the figures, a single gas supply line 418 is connected between the pump 414 and the pump manifold 420. The manifold 420 includes a plurality of electrically actuated solenoid valves 422 located on respective gas supply lines 416, which are responsive to electrical control signals for selectively opening or closing the valves to deliver gas to the inflatable cells 402. Each cell 402 includes a pressure sensitive valve 421 that allows gas to enter but restricts backflow into the gas supply line 416. In other embodiments, the gas delivery system 410 may be replaced by an equivalent fluid delivery system for selectively delivering a fluid, such as water, to the system 400.

Finally, the inflatable airbag system 400 includes an inflation microcontroller 600 configured to generate electrical control signals for controlling the selective inflation of the inflatable cells 402. The microcontroller 600 shown in the figure is the same as the microcontroller of the device 200 and system 300 described above. However, in some embodiments, a separate microcontroller may be used. The control signal is sent to the solenoid valve 422 via control line 424. The microcontroller 600 also controls the start and stop of the pump 414 via control line 426 in conjunction with the control solenoid valve 422.

The pump 414, microcontroller 600, manifold 420, and solenoid valve 422 are preferably integrated within a housing (not shown) of the pump and controller that is positioned adjacent to the system 400. When the air bag system 400 is positioned under a mattress, then the adjacent mattress may have cuts or perforations formed on its bottom in alignment with the cells (depending on the make and model) to allow the air cells to fill the associated lift while making the lift more uniform.

In some embodiments, the inflatable airbag system 400 includes a rigid or semi-rigid layer located below the plurality of inflatable cells for providing structural support. The inflatable airbag system 400 may also include a plurality of engagement straps (not shown) configured to engage the inflatable airbag system with a mattress or bedframe. The elastic sheet may be applied so that it is positioned over the inflatable airbag system 400 to minimize the risk of forming creases that may cause pressure sores. A specially designed mattress may be placed over bladder system 400 and designed to minimize pressure points that may cause pressure sores. This can be achieved by using materials (mainly foam) with different densities for the different parts. For example, soft but thick layers are used near the area where lifting begins to allow the bed to flex; while the harder foam was used to support the low back, about 10cm inside the bed.

Preferably, the gas is air and the gas supply 412 includes a simple gas inlet on the pump 414. However, it should be understood that other types of gases or liquids may be used with the inflatable airbag system 400.

In operation, the unit 402 of the inflatable airbag system 400 is inflated by the microcontroller 600 sending control signals along control line 424 to the solenoid valve 422 and along control line 426 to the pump 414. These control signals indicate which solenoid valves should be opened, and may also indicate other parameters, such as:

the time required to open the solenoid valve 422 and start the pump 414.

The pressure required for the different cells 402 that should be inflated.

The pressure required by the pump 414 to deliver air to the manifold 420.

The speed/power required to start the pump 414.

The volume of air required for delivery to the different units 402.

Upon activation of the pump 414, air is obtained from the gas supply 412 and delivered to the manifold 420 at a first pressure. Depending on which solenoid valves 422 are open, air is delivered to the desired cell 402 at a second pressure, higher than the first pressure, along the respective gas supply lines 416. Once the desired amount of gas delivery is complete, the solenoid valve 422 is closed and the pump 414 is stopped. The pressure sensitive valve 421 of each cell ensures that the gas is maintained at the desired pressure within the respective cell.

When each cell of the system 400 is to be deflated, the microcontroller 600 sends a control signal along control line 424 to open the particular solenoid valve 422 corresponding to the desired cell while the pump 414 is stopped in reverse mode via control line 426. However, in other embodiments, alternative means of venting may be used. For example, microcontroller 600 may also control a separate bleed valve in unit 402 to perform the bleed operation.

In the manner described above, each cell 402 may be individually inflated, deflated, and one of a plurality of predetermined pressure levels. In other embodiments, inflatable cells 402 are divided into groups, each group having a respective electrically actuated solenoid valve 422 common to the group. As such, when the solenoid valve 422 is opened by the microcontroller 600, gas is supplied equally to each unit in the group along a common gas supply line, or along separate gas lines common to the solenoid valves. Furthermore, some or all of the inflatable cells within a stack may be separated by internal electrical or pressure sensitive valves that allow gas to flow from a first cell to a second cell within the stack when the first cell reaches a predetermined pressure threshold. For example, a group may include three vertically adjacent cells located within layers 404, 406, and 408. The gas may be delivered directly to the cells in layer 404 through a dedicated supply line and once the cells reach a predetermined threshold, an internal pressure valve (not shown) is activated to distribute the air to the cells located immediately below in layer 406. Similar processes may occur for the cells in layers 406 and 408. In some embodiments, the internal valves may be controlled by microcontroller 600 for providing further air flow between the cells.

In some embodiments, the gas delivery system 410 does not include a manifold 420, and the gas supply line 416 is directly connected between the pump 414 and the unit 402.

The electrical control signals may be provided by user input through the remote control device 700 or a control panel associated with the inflatable airbag system 400. The user or user may also provide input to a microphone (not shown) through voice commands. For example, the user may select one of a plurality of different predetermined inflation settings (which are different combinations of cells to be inflated or partially inflated). The remote control device 700 may include a touch-sensitive display screen that provides a visual representation of the inflatable airbag system 400 and allows the user to select the cell to be inflated.

In some embodiments, the electrical control signal is based on pressure data received from the system 300 described above. In this manner, inflation of the bladder may be controlled based on the patient's posture and motion detected by the sensor pad system 300. In embodiments where the inflation microcontroller is different from the sensor microcontroller, the sensor microcontroller 600 is configured to transmit pressure data to the inflation microcontroller to control inflation of the bladder based on patient posture and motion.

The electrical control signal may also be provided by an investigative input from a health professional (who may assess whether someone is at a higher risk of getting bedsores) or by a machine learning system (who learns which position pattern may lead to higher comfort or safety).

By integrating control over the sensor mat system 300 and the inflatable airbag system 400, the microcontroller 600 can direct the inflation of the various cells to manipulate the position of the user to minimize the pressure experienced to avoid pressure sores. The past pressure data obtained from the sensor pad system 300 can be processed in conjunction with current or past inflation status information from the inflatable bladder system 400 (via electrical control signals) to direct further inflation modes. The process may be performed by the microprocessor 600 or an external cloud server.

As described above, the microprocessor 600 or an external cloud server may utilize a machine learning protocol that takes inputs from the sensor pad system 300 and determines appropriate control signals for the system 400 to reduce the occurrence of pressure sores, falls, and emergency conditions such as apneas, while improving sleep quality and ergonomic posture recommendations over time. The machine learning may take input from a patient, user, or healthcare professional to increase accuracy and further personalize alerts and recommendations. Input from other devices (e.g., a blood pressure monitor) may be utilized to provide additional content for dynamically adjusting the system 400 appropriately.

The dynamic adjustment of the inflation mode for each cell 402 provides:

performing a massage function to massage deep vein thrombosis of the user or to massage immobile muscles.

Transfer of pressure points on the user to reduce the occurrence of decubitus ulcers.

Forming an obstacle around the edge of the bed to reduce the possibility of falling.

To assist the user in moving, for example, to help them sit up in bed.

Adjusting the neck support by adjusting the pressure of the larger cell 405 to provide additional lift behind the head region.

Providing comfort to users with problems back or other physically well-conditioned people who will feel relaxed and have a better sleep by getting support in certain areas.

Providing ergonomic support for a person in bed (or chair) guided by pressure sensors or user input.

In addition to being integrated with the system 300, the inflatable bladder system may also operate in conjunction with the tiltable bed apparatus 200. In this manner, the particular inflation pattern applied to each cell 402 may take into account whether the user is in a prone or supine position, an inclined position, or a sitting position.

In addition, the microcontroller 600 may take into account the electrical control signals to provide insight into the current inflation status of the airbag when determining the pressure profile of the user by means of the sensor system 300. Thus, the pressure data may be generated based on the received electrical control signals.

In some embodiments, the microcontroller 600 is responsive to the CPR override signal to deflate all of the inflatable cells. The override signal may be received by an associated master override button or may be derived from pressure data that detects a predetermined cardiac arrest event.

28-33 illustrate exemplary inflation profiles of the inflatable airbag system 400 resulting from the inflation of different combinations of cells. Fig. 28, 29, 32, and 33 illustrate a first exemplary inflation profile, while fig. 30 and 31 illustrate a second exemplary inflation profile. Fig. 32 and 33 show the dimensions of an example airbag.

When the inflatable airbag system 400 is used in conjunction with the sensor pad system 300, a plastic, metal, wood, or fabric sheet may be placed under the system 400 for providing resistance to allow the sensors of the sensor pad system 300 to accurately map the position and movement of the user.

Telescopic bed fence system

Referring now to fig. 25-27, a support rail system 900 for a bed is shown. Support rail system 900 includes an engagement structure 902 for engaging bed frame 901. The engagement structure 902 includes an engagement arm 904 extending in a substantially horizontal direction for positioning under a mattress 903 of a bed, as shown in fig. 27. As shown, the engagement arm 904 is comprised of a substantially rectangular frame including parallel members 906 and 908 interconnected by parallel members 910 and 912. However, in other embodiments, the engagement structure 902 may be formed by a single substantially planar panel, a pair of engagement arms, or other engagement means. In some embodiments, the lengths of members 906 and 908 are telescopically extendable to extend across different widths of mattress 903.

The support rail system 900 also includes a support rail 914 mounted on the engagement structure 902 on the member 910 or adjacent to the member 910. The support rail 914 extends in a substantially vertical direction in the operable position and is telescopically adjustable in height between two or more height positions. Telescopic adjustment is performed by a pair of telescopic arms 916 and 918, which comprise two or more telescopic sleeve elements of slightly different diameters, which are slidable relative to each other along a sliding axis. Although not shown, the telescoping arms 916 and 918 are operable to be locked in one of a plurality of height positions by a locking pin (not shown) and a series of longitudinally disposed locking holes (also not shown). The locking pin may be releasably engaged with the locking hole by a corresponding release mechanism (not shown) in a manner similar to a telescoping handle of a luggage case. In other embodiments, the telescoping arms 916 and 918 may be adjusted electronically by the electric actuators in response to control signals (e.g., bluetooth, voice commands, Wi-Fi) received from the microcontroller 600 or other control device.

The support rail 914 is in the form of a substantially planar vertical panel 920, the vertical panel 920 having a flat lower edge 922 and a curved upper edge 924. The support rail 914 also includes holes 926 and 928 to provide handles for extending or retracting the support rail in a vertical direction.

The support rail 914 is rotatable relative to the interface structure 902 via hinged joints 930 and 932 between an operable position (as shown in fig. 25-27) and a collapsed position. The rotation may be performed manually by a rotary release mechanism (not shown). However, in other embodiments, the support bar 914 may be electronically rotated by an electric actuator in response to control signals (e.g., bluetooth, voice commands, Wi-Fi) issued by the microcontroller 600 or other control device.

Finally, a pair of support legs 934 and 936 extend substantially downward and slightly outward from the engagement structure 902 at an angle of 15-75 degrees relative to vertical. However, in other embodiments, the support legs 934 and 936 are disposed substantially vertically downward. The support legs 934 and 936 are adjustable in length to engage the floor adjacent the bed to hold the support rail 914 in an operable position against the mattress 903. Each support leg includes an abutment structure 938 and 940 formed of rubber or similar material to provide a frictional engagement with the floor. This frictional engagement, together with the slight outward tilt of the support legs 934 and 936, provides sufficient force to hold the user in the bed even if the user's weight is applied to the support rail 914.

The support legs 934 and 936 are formed from a plurality of telescoping sleeve elements (e.g., 942 and 944) to enable the length of the support legs to be telescopically adjusted. This allows the support legs to be adjustable for beds of different heights.

As with the telescoping arms 916 and 918 described above, telescopic adjustment of the support legs 934 and 936 is performed by manually actuating a releasable locking pin (not shown) into one of a series of longitudinally disposed locking holes (also not shown) to lock the support legs in one of a plurality of height positions. The locking pin is releasably engaged with the locking hole by a corresponding release mechanism (not shown) in a manner similar to the telescoping handle of a travel container. In some embodiments, actuation of the locking pin may be performed electronically by an electric actuator in response to a control signal (e.g., bluetooth, voice command, Wi-Fi) from microcontroller 600 or similar control device.

The various components of the support rail system 900 may be formed from plastic, metal, or other rigid materials.

In operation, the support rail system 900 may be placed along a side of a bed or at the head or tail of a bed. The system 900 may be associated with the tilting bed apparatus 200 by a flexible sheet or Velcro and/or other material, the surface layer of which is attached to the system 900. Multiple support rail systems may be used in conjunction with one another to provide support to a user around multiple sides/ends of the bed. When installed in an operable position, the support rail system 900 takes advantage of the weight of the mattress 903 and the weight of the user applied thereto to reduce the chance of falling.

When getting out of bed, the user folds the support rail 914 to a folded position in which it extends downwardly in a substantially vertical direction adjacent the support legs 934 and 936. In some embodiments, the support rail 914 is detachable from the support structure 902 so that a user can get out of bed. The support bar 914 may be folded down via the core APP in communication with the microcontroller 600 by manual activation of a button (as described above), voice command, or remote control by the user or medical personnel. The support legs 934 and 936 may also be retracted when the support rail 914 is moved from the operable position to the storage position. The support legs can be folded into close proximity to the support rail 914 to reduce the risk of a user falling or tripping over the support legs when getting out of bed.

It should be appreciated that in other embodiments, the support rail system 900 may include only one support leg or more than two support legs. In another embodiment, the support rail system 900 includes other structures, such as an associated dinning table, bottle/cup holder, and/or a charging port for charging the electronic device while the user is in bed.

Conclusion

The system described above provides an affordable alternative bed system to help patients recover from injury and reduce the incidence of falls and pressure sores. Although the above aspects of the present invention are described separately, each of them can be configured as a single smart bed system. This intelligent bed system can be used for:

lift the patient or infirm person, providing them with a sense of safety and comfort at home.

Lifting people who want to work comfortably in bed or using a laptop, by doing so, reduces their chances of suffering from work related illnesses.

Lift the person with the sleep problem at different elevations (determined by an associated software algorithm or application) to provide them with a dipping sleep therapy.

Reducing the occurrence of preventable accidents, such as falls and bedsores.

Accelerate the recovery and reduce the total hospitalization time.

When the above tiltable bed system is mounted on an existing bed frame, it is easier for disabled patients to move around. Because the system is not a spring-based design, there are fewer mechanical parts subject to wear. The actuatable balloon system may increase patient comfort and may provide a greater degree of adjustment through user input of a remote control, voice input, and/or feedback from a sensor system.

The smart bed system can also connect other devices and sensors from the monitoring device to the smart lights/blinds through the microcontroller.

Explanation of the invention

Unless specifically stated otherwise, as apparent from the following discussions, it is appreciated that throughout the specification discussions utilizing terms such as "processing," "computing," "calculating," "determining," "analyzing," or the like, refer to the action and/or processes of a computer or computing system, or similar electronic computing device, that modify and/or transform data represented as physical, such as electronic, quantities into other data similarly represented as physical quantities.

In a similar manner, the terms "controller" or "processor" may refer to any device or portion of a device that processes electronic data, such as from registers and/or memory, to transform that electronic data into other electronic data that may be stored, for example, in registers and/or memory. A "calculator" or "computer" or "computing platform" may include one or more processors.

Reference throughout this specification to "one embodiment," "some embodiments," or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of the phrases "in one embodiment," "in some embodiments," or "in an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments as would be apparent to one of ordinary skill in the art.

As used herein, unless otherwise specified the use of the ordinal adjectives "first", "second", "third", etc., to describe a common object, merely indicate that different instances of like objects are being referred to, and are not intended to imply that the objects so described must be in a given sequence, either temporally, spatially, in ranking, or in any other manner.

In the claims and the present specification, the term "comprising" is an open-ended term meaning that at least the following elements/features are included, but not excluding others. Accordingly, when the term "comprising" is used in the claims, it should not be interpreted as limiting the means or elements or steps listed thereafter. For example, the scope of "a device includes a and B" should not be limited to devices consisting of only components a and B. The term "comprising" as used herein is also an open-ended term that also means including at least the elements/features that follow the term, but does not exclude the presence of others. Thus, "comprising" and "including" are synonymous.

It should be appreciated that in the foregoing description of exemplary embodiments of the invention, various features of the invention are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of one or more of the various inventive aspects. However, the method of the present invention should not be construed as reflecting the intent: the claims require more features than are expressly recited in each claim. Indeed, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing described embodiment. Thus, the following claims are hereby expressly incorporated into this detailed description, with each claim standing on its own as a separate embodiment of this invention.

Furthermore, although some embodiments described herein include some but not other features included in other embodiments, it will be understood by those skilled in the art that combinations of features of different embodiments are also encompassed by the invention, forming different embodiments. In the claims, any of the claimed embodiments may be used in any combination.

Various specific details are set forth in the description. However, it is understood that embodiments of the invention may be practiced without these specific details. In other instances, well-known methods, structures and techniques have not been described in detail so as not to obscure the present invention.

Similarly, it should be noted that when the term "coupled" is used in the claims, it should not be construed as being limited to direct connections only. The terms "coupled" and "connected," along with their derivatives, may be used. It should be understood that these terms are not intended as synonyms for each other. Thus, the scope of "device a coupled to device B" should not be limited to devices or systems in which the output of device a is directly connected to the input of device B. This means that there is a path between the output of a and the input of B that includes other devices or means. "coupled" may mean that two or more elements are in direct physical, electrical, or optical contact, or that two or more elements are not in direct contact with each other, but yet still co-operate or interact with each other.

The embodiments described in this specification are intended to cover any adaptations or variations of the present invention. While the invention has been described and illustrated with reference to specific exemplary embodiments, those skilled in the art will recognize that other embodiments can be readily devised which fall within the scope of the invention.