CN108445817B - Intelligent bed, control method thereof and intelligent bed system - Google Patents

Abstract

The invention relates to an intelligent bed, a control method thereof and an intelligent bed system, and belongs to the field of intelligent home application. The smart bed comprises: a support base; the telescopic support comprises a plurality of telescopic support columns which are arranged in an array mode, wherein one ends of the telescopic support columns are fixed on the supporting seat, the other ends of the telescopic support columns can form bearing surfaces with at least two shapes, and the bearing surfaces are used for bearing a human body. The intelligent bed solves the problem that the intelligent bed has single function. The invention is used for sleeping of the user.

Description

Intelligent bed, control method thereof and intelligent bed system

Technical Field

The invention relates to the field of intelligent home application, in particular to an intelligent bed, a control method thereof and an intelligent bed system.

Background

With the improvement of the living standard of people, the pursuit of people on the living quality is also improved. While two-thirds of the life of a person spends in sleep, beds are an essential living article for people. At present, the types of beds are more and more, and the beds comprise a hard bed, a soft bed and the like, and one of the beds can be selected according to own hobbies and demands.

However, the comfort level of these beds cannot meet the pursuit of high-quality life by the existing consumers, and an intelligent bed is presented at present aiming at the problems existing in the prior art. The bed is provided with a plurality of acquisition units on the bed body for acquiring relevant data of the body of a user sleeping on the intelligent bed so as to provide the user with the data.

The function of such smart beds remains relatively single.

Disclosure of Invention

The embodiment of the invention provides an intelligent bed, a control method thereof and an intelligent bed system, which can solve the problem that the intelligent bed has single function. The technical scheme is as follows:

according to a first aspect of an embodiment of the present invention, there is provided a smart bed comprising:

a support base;

the telescopic support comprises a plurality of telescopic support columns which are arranged in an array mode, wherein one ends of the telescopic support columns are fixed on the supporting seat, the other ends of the telescopic support columns can form bearing surfaces with at least two shapes, and the bearing surfaces are used for bearing a human body.

Optionally, a detection module for a target parameter is further disposed at the other end of at least one of the plurality of telescopic struts, and the target parameter includes at least one of physiological data, pressure and temperature.

Optionally, the smart bed further comprises:

the first communication module is connected with the detection module and is configured to acquire data acquired by the detection module within a specified duration and transmit the acquired data to a specified device.

Optionally, the smart bed further comprises:

a temperature adjustment assembly located at a gap of the plurality of telescoping struts, the temperature adjustment assembly configured to adjust a temperature of the bearing surface.

Optionally, the smart bed further comprises:

a control assembly; or, a control component and a second communication module;

wherein the control assembly is respectively connected with the plurality of telescopic struts, and the control assembly is configured to control the lifting of each telescopic strut;

the second communication module is coupled to the control assembly and is configured to establish a communication connection of the control assembly to a designated device.

Optionally, the smart bed further comprises:

the alarm clock assembly is connected with the telescopic support posts and is configured to control the telescopic support posts to move when reaching a specified moment, so that the bearing surfaces of the telescopic support posts are in specified shapes.

Optionally, a rigid spherical structure is disposed at the other end of each telescopic strut, a cavity is disposed in the spherical structure of at least one telescopic strut of the plurality of telescopic struts, and a temperature adjusting assembly is disposed in the cavity, and the temperature adjusting assembly comprises at least one of a heater and a refrigerator.

Optionally, the detection module includes temperature sensor and pressure sensor, every the outside cladding of globular structure has first rete and second rete respectively, be provided with at least one on the first rete temperature sensor, be provided with at least one on the second rete pressure sensor.

According to a second aspect of embodiments of the present invention, there is provided a control method of a smart bed, where the smart bed is any one of the smart beds described in the first aspect, the method including:

acquiring a control instruction, wherein the control instruction is used for indicating the shape of a bearing surface of the intelligent bed, and the bearing surface is used for bearing a human body;

and controlling the telescopic struts to move based on the control instruction, so that the bearing surfaces of the telescopic struts are in the shapes indicated by the control instruction.

According to a third aspect of embodiments of the present invention, there is provided a smart bed system comprising: the smart bed of any one of the first aspects above, and a control device for controlling the smart bed.

The technical scheme provided by the embodiment of the invention can comprise the following beneficial effects:

according to the intelligent bed, the control method thereof and the intelligent bed system provided by the embodiment of the invention, as the plurality of telescopic struts are arranged on the supporting seat, the plurality of telescopic struts can form the bearing surfaces with at least two shapes, so that the shape of the bearing surface of the intelligent bed is changeable, and the functions of the intelligent bed are enriched.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention as claimed.

Drawings

In order to more clearly illustrate the embodiments of the present invention, the drawings that are required for the description of the embodiments will be briefly described below, it being apparent that the drawings in the following description are only some embodiments of the present invention and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a schematic diagram of a smart bed according to an exemplary embodiment;

FIG. 2 is a schematic diagram of another smart bed configuration shown in accordance with an exemplary embodiment;

FIG. 3 is a schematic diagram of a structure of yet another smart bed, shown according to an exemplary embodiment;

FIG. 4 is a schematic illustration of a telescoping post structure according to an exemplary embodiment;

FIG. 5 is a schematic structural view of another telescoping post shown in accordance with an exemplary embodiment;

FIG. 6 is a block diagram of a smart bed shown according to an exemplary embodiment;

FIG. 7 is a schematic diagram of a configuration of a mode switch button, according to an exemplary embodiment;

FIG. 8 is a block diagram of another smart bed shown according to an exemplary embodiment;

FIG. 9 is a block diagram of yet another smart bed shown in accordance with an exemplary embodiment;

FIG. 10 is a block diagram of yet another smart bed shown in accordance with an exemplary embodiment;

fig. 11 is a flowchart illustrating a control method of a smart bed according to an exemplary embodiment.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

To meet the needs of users, an intelligent bed is currently presented. The bed is provided with a plurality of acquisition units on the bed body for acquiring relevant data of the body of a user sleeping on the intelligent bed so as to provide the user with the data. But the smart bed has a single function.

The embodiment of the invention provides an intelligent bed 1, which can enrich functions of the intelligent bed, as shown in fig. 1, the intelligent bed 1 comprises:

a support base 11; a plurality of telescopic struts 12 arranged in an array, one end a of the plurality of telescopic struts 12 is fixed on the supporting seat 11, and the other end b of the plurality of telescopic struts 12 can form a bearing surface W of at least two shapes for bearing a human body.

In summary, according to the intelligent bed provided by the embodiment of the invention, since the plurality of telescopic struts are arranged on the supporting seat, the plurality of telescopic struts can form the bearing surfaces with at least two shapes, thereby realizing the shape variability of the bearing surfaces of the intelligent bed and enriching the functions of the intelligent bed.

In an alternative implementation, the carrying surface W may form a pillow-integrated shape, i.e. in the carrying surface W the telescopic struts 12 near the head area form a pillow shape, the telescopic struts 12 in the other areas form a bed surface for sleeping. Therefore, the intelligent bed can be used for saving cost without placing a pillow, and meanwhile, the functions of the intelligent bed are enriched. Further, the height of the pillow formed by the telescopic strut 12 can be adjusted according to the needs of the user.

In the embodiment of the invention, the intelligent bed can be further provided with a temperature adjusting component, the temperature adjusting component is configured to adjust the temperature of the bearing surface W so as to adjust the temperature of the intelligent bed, a user can control the temperature adjusting component to adjust the temperature according to own requirements, and particularly in different seasons, the user can change the temperature of the bed body along with the change of the seasons by controlling the temperature adjusting component. Thereby effectively improving and (5) user experience. When the temperature adjusting component comprises a heater, compared with a traditional electric blanket, the temperature adjusting component is simpler, more convenient and safer to use.

The temperature adjusting component can have various implementation modes, and the embodiment of the invention is illustrated by taking the following two implementation modes as examples:

in a first possible implementation, the temperature regulating assembly 13 is located at the gap of the plurality of telescopic struts 12. The temperature regulating assembly 13 may include at least one of a heater, a refrigerator, and a fan. In general, the temperature adjusting assembly 13 may include a heater for heating the smart bed, a refrigerator for cooling the smart bed, and a fan for controlling the flow of air to increase the dissipation of heat and achieve a cooling effect. As shown in fig. 2, the temperature adjusting components 13 may be plural, and the plural temperature adjusting components 13 may be distributed at the gaps of the plural telescopic struts 12, and as the user generally sleeps on the upper half of the smart bed, that is, the region near the bed head, the plural temperature adjusting components 13 may be distributed in a concentrated manner; optionally, the plurality of temperature adjusting components 13 may be uniformly distributed at the gaps of the plurality of telescopic struts 12, so as to ensure uniform adjustment of temperature; fig. 2 illustrates the smart bed with three temperature adjustment assemblies 13 disposed near the bed head, but the number of temperature adjustment assemblies 13 is not limited.

In a second possible implementation form of the method, the temperature regulating assembly 13 may be located on the outer wall of the telescopic strut 12 or inside the telescopic strut 12. The temperature regulating assembly 13 may include at least one of a heater for heating the smart bed and a refrigerator for cooling the smart bed. As shown in fig. 3, fig. 3 illustrates an example in which the temperature adjustment assembly 13 is located on the outer wall of the telescopic strut 12 of the smart bed, but the location where the temperature adjustment assembly 13 is located is not limited.

By way of example, as shown in fig. 4, fig. 4 illustrates an example in which the temperature adjustment assembly 13 is located inside the telescopic struts 12 of the smart bed, the other end b of each telescopic strut 12 is provided with a rigid spherical structure 121, a cavity is provided in the spherical structure of at least one telescopic strut 12 of the plurality of telescopic struts, the temperature adjustment assembly 13 is provided in the cavity, and the temperature adjustment assembly 13 may include at least one of a heater for heating the smart bed and a refrigerator for cooling the smart bed.

Optionally, the other end of at least one telescopic strut 12 of the plurality of telescopic struts 12 is further provided with a detection module 14 for a target parameter, the target parameter including at least one of physiological data, pressure and temperature, the physiological data may include: at least one of heart rate, blood pressure, and brain waves, which may reflect a state of a user while sleeping. Optionally, the target parameter may further include other parameters, such as humidity, which is not limited by the embodiment of the present invention. The detection module 14 of the target parameter may consist of one or more corresponding instruments. For example, when the target parameter includes a heart rate, the detection module 14 of the target parameter includes a heart rate tester, when the target parameter includes a blood pressure, the detection module 14 of the target parameter includes a blood pressure meter, when the target parameter includes an brain wave, the detection module 14 of the target parameter includes a brain wave meter, when the target parameter includes a pressure, the detection module 14 of the target parameter includes a pressure detection module, and when the target parameter includes a temperature, the detection module 14 of the target parameter includes a temperature detection module. The pressure detection module can detect the pressure, which may be a pressure sensor. The temperature detection module can detect temperature, and can be a temperature sensor.

Further, the detection module 14 and the temperature adjusting component 13 may be disposed on the telescopic support 12, so that the space in the bed body may be fully utilized, and the integration level of the components may be improved. For example, the detection module 14 includes a temperature sensor x1 and a pressure sensor x2.

As shown in fig. 5, the other end b of each telescopic strut 12 is provided with a rigid spherical structure 121, the outer part of the spherical structure 121 is respectively covered with a first film layer 1211 and a second film layer 1212, at least one temperature sensor x1 is disposed on the first film layer 1211, the at least one temperature sensor x1 and the first film layer 1211 may be in an integral structure, and at least one pressure sensor x2 is disposed on the second film layer 1212, and the at least one pressure sensor x2 and the second film layer 1212 may be in an integral structure. The first film layer 1211 and the second film layer 1212 may be stacked in a direction away from the spherical structure 121, or may be stacked in a direction close to the spherical structure 121, which is not limited in the embodiment of the present invention. The two film layers can be in direct contact with a human body to sense the change of pressure and temperature, and the two film layers are not affected by each other. Fig. 5 illustrates an example in which the second film 1212 is coated outside the first film 1211.

Optionally, as shown in fig. 6, the smart bed may further include:

the first communication module 15, the first communication module 15 is connected with the detection module 14, and the first communication module 15 is configured to acquire data acquired by the detection module 14 in a specified duration and transmit the acquired data to the specified device. The designating device may be a mobile terminal, such as a mobile phone or a computer, through which a user can view the data collected by the detection module 14 to understand the conditions of target parameters such as temperature and pressure collected by the smart bed. Further, the user may forward the data to the device of the telemedicine health system via the designated device, which provides reasonable life advice information based on the data.

In the embodiment of the present invention, the smart bed may be controlled to form a bearing surface W with various shapes, and the manner in which the smart bed is controlled may be various, for example, a close-range control manner and a remote control manner, and the embodiment of the present invention is described by taking the two manners as examples respectively:

for the close range control mode, in an alternative implementation mode, a user can control the intelligent bed nearby the intelligent bed, and an external control component such as a control button or a control rocker can be arranged on the intelligent bed for the user to apply control actions. As shown in fig. 7, taking the external control unit as an example of the mode switching button 16, the mode switching button 16 is respectively connected to the plurality of telescopic struts 12 (not shown in the drawing), and the mode switching button 16 has at least two gear positions, each gear position corresponds to a shape of the bearing surface W, and each shape corresponds to a mode of the bearing surface W. In an alternative manner, as shown in fig. 7, the mode switch button 16 may have 3 gears, corresponding to a hard bed mode, a soft bed mode and a healthy mode, respectively, for example, in fig. 7, gear 1 may correspond to the bearing surface W of the smart bed being a hard bed mode, gear 2 may correspond to the bearing surface W of the smart bed being a soft bed mode, and gear 3 may correspond to the bearing surface W of the smart bed being a healthy mode, where the hard bed mode refers to the bearing surface W forming a designated plane with a fixed shape, which may be parallel to a horizontal plane, as an example; the soft bed mode means that the bearing surface W forms a movable curved surface, and the curved surface can be changed along with the sleeping posture of a user; the health mode means that the bearing surface W forms a designated curved surface, which is a curved surface suitable for sleeping of a human body. In another alternative, the mode switch button 16 may have 2 gears, which are a plane mode and a curved surface mode, respectively, for example, the gear 1 may correspond to the bearing surface W of the smart bed being a plane mode, and the gear 2 may correspond to the bearing surface W of the smart bed being a curved surface mode, where the plane mode refers to the bearing surface W forming a designated plane, which may be parallel to a horizontal plane, as an example; the curved surface mode means that the bearing surface W forms a specified curved surface. Of course, the modes of the above-mentioned respective bearing surfaces W may be set according to specific situations, for example, the mode switch button 16 further includes a gear corresponding to a pillow-integrated mode, which refers to that the bearing surfaces W form the above-mentioned pillow-integrated shape, which is not limited in the embodiment of the present invention.

In another alternative implementation, the smart bed may automatically take its own control. By way of example, the smart bed as shown in fig. 8 may further include:

and a control assembly 17, the control assembly 17 being connected to the plurality of telescopic struts 12, respectively, the control assembly 17 being configured to control the elevation of each telescopic strut 12. The control assembly 17 may be a processor or a processing chip.

As described above, the control unit 17 may control the telescopic struts 12 in a plurality of ways to control the bearing surface W to switch between different modes according to the various shapes of the bearing surface W formed by the telescopic struts 12, and the following embodiments of the present invention are described by way of example:

in a first mode, the control assembly 17 controls the telescopic support 12 in a preset control mode. For example, at the time of shipment of the smart bed, the control assembly 17 may be preset with a control mode, or the control assembly 17 may periodically update the control mode through a corresponding server, and the control assembly 17 controls the telescopic strut 12 based on the control mode. For example, the control manner may be a control manner based on a time period, that is, in different time periods, the bearing surface W corresponds to different modes, for example, in daytime, the intelligent bed corresponds to a hard bed mode, and in evening, the intelligent bed corresponds to a soft bed mode; for another example, the control manner may be a control manner based on seasons, that is, the bearing surface W corresponds to different modes in different seasons, for example, the smart bed corresponds to a soft bed mode in spring and autumn, and the smart bed corresponds to a health mode in summer and winter. The embodiment of the present invention is not limited thereto.

In a second way, the control assembly 17 dynamically controls the telescopic strut 12. Alternatively, the control module 17 may be connected to the detection module 14 for the target parameter, and control the telescopic strut 12 based on the detection result of the detection module 14 for the target parameter. For example, the control assembly 17 may control the telescoping struts 12 based on at least one of physiological data, pressure, temperature, and humidity.

For example, when the detection module 17 includes a pressure detection module, the pressure detection module may collect data of pressure applied to the pressure detection module by various parts of the body after the user is lying in the bed and transmit the data of the pressure to the control module 17, and the control module 17 determines posture data suitable for sleeping of the user according to the data of the pressure, and adjusts the plurality of telescopic struts 12 based on the posture data. The control component 17 may query the preset correspondence between the pressure and the gesture to obtain gesture data through the data of the pressure, or the control component 17 may calculate to obtain the gesture data by using a preset formula based on the data of the pressure, which is not limited in the embodiment of the present invention.

For example, when the detection module 14 includes a temperature detection module, the temperature detection module may collect data of temperatures of various parts of the body of the user after lying in the bed and transmit the data of temperatures to the control assembly 17, and the control assembly 17 determines posture data suitable for sleeping of the user according to the data of temperatures, and adjusts the plurality of telescopic struts 12 based on the posture data. The control component 17 may query a preset corresponding relationship between the temperature and the gesture based on the temperature data to obtain gesture data, or the control component 17 may calculate to obtain gesture data by using a preset formula based on the temperature data, which is not limited in the embodiment of the present invention.

Alternatively, the control unit 17 may be connected to a temperature control unit, and the control unit 17 may control the temperature control unit based on data of the temperature detected by the temperature detection module. For example, when the temperature corresponding to the temperature data is smaller than the first specified temperature threshold, the control module 17 controls the temperature control module to heat the carrying surface W until the temperature corresponding to the temperature data is greater than or equal to (typically equal to) the specified temperature threshold; when the temperature corresponding to the temperature data is greater than the second specified temperature threshold, the control component 17 controls the temperature control component to cool the bearing surface W until the temperature corresponding to the temperature data is less than or equal to (usually equal to) the second specified temperature threshold.

For the remote control mode, the smart bed may be remotely controlled by a designated device by communicating with the device, and accordingly, the user may remotely control the smart bed through the device.

By way of example only, the present invention is directed to a method of, the smart bed as shown in fig. 8 may further include:

and a control assembly 17, the control assembly 17 being connected to the plurality of telescopic struts 12, respectively, the control assembly 17 being configured to control the elevation of each telescopic strut 12.

Optionally, as shown in fig. 9, the smart bed may further include: a second communication module 18, the second communication module 18 being connected to the control assembly 17, the second communication module 18 being configured to establish a communication connection of the control assembly 17 with a designated device. The designation means may be a mobile terminal, such as a cell phone or a computer.

Alternatively, the first communication module 15 and the second communication module 18 may be the same communication module, and the designating device that establishes communication connection with the first communication module 15 and the second communication module 18 may be the same designating device, in which case the designating device may obtain the detection result of the target parameter, and control the telescopic strut 12 based on the detection result of the target parameter. For example, the control assembly 17 may be remotely controlled by a prescribed device, which may control the telescoping mast 12 based on at least one of physiological data, pressure, temperature, and humidity.

For example, when the detection module 14 includes a pressure detection module, the pressure detection module may collect data of the pressure applied to the pressure detection module by various parts of the body after the user is in the bed and transmit the data of the pressure to a designation device, which determines posture data suitable for the user to sleep from the data of the pressure, transmits the posture data to the control assembly 17, and adjusts the plurality of telescopic struts 12 based on the posture data by the control assembly 17. The designating device can acquire gesture data by inquiring a preset corresponding relation between pressure and gesture based on the pressure data, the designating device can calculate the gesture data by adopting a preset formula based on the pressure data, and the designating device can determine the gesture data according to the control of designated personnel. The embodiment of the present invention is not limited thereto.

For example, when the detection module 14 includes a temperature detection module, the temperature detection module may collect data of temperatures of various parts of the body of the user after lying in the bed and transmit the data of the temperatures to a designation device, which determines posture data suitable for the sleep of the user according to the data of the temperatures, transmits the posture data to the control assembly 17, and adjusts the plurality of telescopic struts 12 based on the posture data by the control assembly 17. The specifying device may query a preset corresponding relationship between the temperature and the gesture based on the temperature data to obtain gesture data, or may calculate to obtain gesture data by using a preset formula based on the temperature data, which is not limited in the embodiment of the present invention.

Alternatively, the second communication module 18 may be connected to a temperature control module, and the specifying means may remotely control the temperature control module through the control module 17 based on the data of the temperature detected by the temperature detection module. For example, when the temperature corresponding to the temperature data is smaller than the first specified temperature threshold, the specified device remotely controls the temperature control component to heat the bearing surface W through the control component 17 until the temperature corresponding to the temperature data is greater than or equal to (usually equal to) the specified temperature threshold; when the temperature corresponding to the temperature data is greater than the second designated temperature threshold, the designated device remotely controls the temperature control component to cool the bearing surface W through the control component 17 until the temperature corresponding to the temperature data is less than or equal to (usually equal to) the second designated temperature threshold.

For the second mode of the above-described close range control mode and the remote control mode, the first specified temperature threshold is generally smaller than the second specified temperature threshold. For example, the first specified temperature threshold is 10 degrees or 15 degrees, and the second specified temperature threshold is 30 degrees or 25 degrees. The first and second specified temperature thresholds may be set according to a user's demand or a change in seasons. In the two modes, the control component can control the temperature control component according to the requirement of a user or the change of seasons so as to heat or refrigerate the bed body, and the user experience is improved.

Further, in the remote control mode, the designating device can remotely control the temperature control assembly to heat or cool the bed body in advance, for example, the designating device is a mobile terminal such as a mobile phone, in winter, a user can remotely control the bed body to heat in advance through the mobile phone before returning home, and in summer, the user can remotely control the bed body to cool in advance through the mobile phone before returning home.

The above embodiment is described taking the example that the specifying means is connected to the control module 17 via the second communication module 18, and in an alternative implementation, the specifying means may also be directly connected to other modules of the smart bed via the second communication module 18, for example, directly connected to the temperature adjusting module via the second communication module 18, and/or directly connected to the target parameter detecting module 14 via the second communication module 18.

In an embodiment of the present invention, in one aspect, the specifying device may include a mobile terminal of a user; in another aspect, the specified device may comprise a device of a remote medical health system, which may be one or more medical computers, or one or more medical servers. After the direct or indirect communication connection is established between the specifying device and the detection module 14 of the target parameter, the specifying device can acquire a detection result of the target parameter and provide life suggestion information based on the detection result of the target parameter, and the intelligent bed can further comprise a presentation module, wherein the life suggestion information can be presented to a user through the presentation module of the intelligent bed, and the presentation module can be a display screen or a voice prompt for example; or the appointed device sends the life suggestion information to the terminal of the user, the terminal presents the life suggestion information to the user, and the terminal can present the life suggestion information in the form of voice or image. The life advice information may include a reasonable sleep period and/or a reasonable sleep posture, etc., to which embodiments of the present invention are not limited.

Optionally, the smart bed further comprises:

the alarm clock assembly 19, the alarm clock assembly 19 is configured to wake up the user. In an alternative implementation, as shown in fig. 10, the alarm clock assembly 19 is connected to the plurality of telescopic struts 12, and the alarm clock assembly 19 is configured to control the movement of the plurality of telescopic struts 12 when a specified time is reached, such that the carrying surface W of the plurality of telescopic struts 12 takes a specified shape, which may be a shape in which an area of the carrying surface W for carrying the head of the user protrudes by a specified height with respect to other areas. For example, when the specified time is reached, the alarm clock assembly 19 can control the telescopic struts 12 to move so that the bearing surface W forms a bending surface with an L-shaped section, and thus, the human body can be pushed up, and the purpose of waking up the sleeping user is achieved. It should be noted that, in this alternative manner, the alarm clock assembly 19 may be integrally formed with the control assembly 17, and the functions thereof may be implemented by software. In another alternative implementation, the alarm clock assembly 19 may also be configured to emit a prompt tone when a specified time is reached to wake up a sleeping user, the outside of the smart bed may be provided with a control button for controlling the alarm clock assembly 19, the user may turn off the prompt tone for waking up the alarm clock assembly 19 by controlling the control button, in this alternative implementation, the alarm clock assembly 19 may be a mechanical alarm clock or a structure obtained by combining a timer and a speaker, the alarm clock assembly may be provided at the head of the smart bed, or at the gaps of the plurality of telescopic struts 12, to form an effective audible prompt for the user.

In summary, since the plurality of telescopic struts are arranged on the supporting seat of the intelligent bed provided by the embodiment of the invention, the telescopic struts can form bearing surfaces of at least two shapes, so that the shape of the bearing surface of the intelligent bed is changeable, and the functions of the intelligent bed are enriched. Further, the intelligent bed can be controlled in a short distance or in a long distance, and user experience can be effectively improved.

The embodiment of the invention provides an intelligent bed system, which comprises: the smart bed according to any one of the above embodiments of the present invention, and a control device for controlling the smart bed. The control device may be the designated device in the above embodiment, or may be another device, which is not limited in the embodiment of the present invention.

An embodiment of the present invention provides a method for controlling an intelligent bed, where the intelligent bed is any one of the intelligent beds provided in the foregoing embodiments, as shown in fig. 11, and the method includes:

step 101, obtaining a control instruction, wherein the control instruction is used for indicating the shape of a bearing surface of the intelligent bed, and the bearing surface is used for bearing a human body.

And 102, controlling the telescopic struts to move based on the control instruction, so that the bearing surfaces of the telescopic struts are in the shapes indicated by the control instruction.

In summary, since the plurality of telescopic struts are arranged on the supporting seat, the intelligent bed provided by the embodiment of the invention can control the movement of the plurality of telescopic struts according to the control instruction, so that the bearing surfaces of the plurality of telescopic struts are in the shape indicated by the control instruction, thereby realizing the shape change of the bearing surface of the intelligent bed and enriching the functions of the intelligent bed.

It should be noted that, the above-mentioned ways of obtaining the control instruction in step 101 may be various, and the following three obtaining ways are taken as examples for the embodiment of the present invention:

in the first acquisition mode, the intelligent bed can receive a control instruction sent by the control device.

The obtaining process may refer to a remote control manner in the above device embodiment, where the smart bed includes a control component and a second communication module, and the control device may be the above specified device, and after determining the gesture data, the control device transmits the gesture data to the control component of the smart bed through a control instruction. Accordingly, in step 102, the smart bed controls the movement of the plurality of telescopic struts based on the control command, so that the bearing surfaces of the plurality of telescopic struts are in shapes corresponding to the gesture data.

In a second obtaining manner, as shown in fig. 2, the other end of at least one of the plurality of telescopic struts is further provided with a detection module for the target parameter, and accordingly, the process of obtaining the control instruction may include:

and receiving data acquired by a detection module of a target parameter, and generating a control instruction based on the acquired data, wherein the target parameter comprises at least one of physiological data, pressure and temperature.

The acquisition process may refer to the process that the control assembly performs the control of the telescopic strut in the device embodiment described above, and may refer to the process that the control assembly performs the dynamic control of the telescopic strut in particular. After the control component determines the gesture data, the generated control instructions include the gesture data. Accordingly, in step 102, the smart bed controls the movement of the plurality of telescopic struts based on the control command, so that the bearing surfaces of the plurality of telescopic struts are in shapes corresponding to the gesture data.

The third acquisition mode, as shown in fig. 7 above, the smart bed may further include: the mode switching button is respectively connected with the telescopic struts, and is provided with at least two gears, and each gear corresponds to the shape of one bearing surface, so that the process of acquiring the control instruction can comprise the following steps:

after the gear change of the mode switching button is detected, a control instruction is generated, and the control instruction is used for indicating the shape corresponding to the switched gear.

The acquisition process may refer to the manner of the close-range control in the above-described device embodiment, and particularly to the control process of the mode switching button 16 shown in fig. 7. After the user applies a control action to the mode switching button, the intelligent bed checks the gear change of the mode switching button, and generates a control instruction, wherein the control instruction comprises the gear after switching. Correspondingly, in step 102, the intelligent bed controls the plurality of telescopic struts to move based on the gear switched in the control instruction, so that the bearing surfaces of the plurality of telescopic struts are in shapes corresponding to the gear.

The above-mentioned manner of obtaining the control command may also have other manners, which are only schematically illustrated in the embodiment of the present invention, and are not limited thereto.

The intelligent bed provided by the embodiment of the invention can be applied to the control method of the intelligent bed, and the method in the embodiment of the invention can refer to the working flow and working principle of each module, so that the description is omitted.

In summary, according to the control method for the intelligent bed provided by the embodiment of the invention, since the plurality of telescopic struts are arranged on the supporting seat, the intelligent bed can control the movement of the plurality of telescopic struts according to the control instruction, so that the bearing surfaces of the plurality of telescopic struts are in the shape indicated by the control instruction, the shape of the bearing surface of the intelligent bed is changeable, and the functions of the intelligent bed are enriched.

In the embodiment of the present invention, the term "and/or" is merely an association relationship describing the association object, which indicates that three relationships may exist, for example, a and/or B may indicate: a exists alone, A and B exist together, and B exists alone. In addition, the character "/" herein generally indicates that the front and rear associated objects are an "or" relationship.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

It is to be understood that the invention is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims (3)

1. An intelligent bed, characterized by comprising:

a support base;

the telescopic support comprises a plurality of telescopic support columns arranged in an array, wherein one ends of the telescopic support columns are fixed on a supporting seat, the other ends of the telescopic support columns can form bearing surfaces with at least two shapes, the bearing surfaces are used for bearing a human body, and the bearing surfaces are used for forming a shape of bed and pillow integration;

the other end of at least one telescopic strut of the plurality of telescopic struts is also provided with a detection module of a target parameter, the target parameter comprises at least one of physiological data, pressure, temperature and humidity, and the physiological data comprises: at least one of heart rate, blood pressure and brain waves;

a control assembly and a second communication module;

wherein the control assembly is respectively connected with the plurality of telescopic struts, and the control assembly is configured to control the lifting of each telescopic strut;

the second communication module is connected with the control assembly and is configured to establish communication connection between the control assembly and a designated device which remotely controls the control assembly and controls the telescopic strut based on at least one of the physiological data, pressure, temperature and humidity;

the alarm clock assembly is connected with the telescopic support posts, is configured to control the telescopic support posts to move when a specified time is reached, enables the bearing surfaces of the telescopic support posts to be in a specified shape, and enables the bearing surfaces to be in a shape that the areas for bearing the heads of users protrude by specified heights relative to other areas, and is integrally structured with the control assembly;

the other end of each telescopic strut is provided with a rigid spherical structure, a cavity is arranged in the spherical structure of at least one telescopic strut in the plurality of telescopic struts, a temperature adjusting component is arranged in the cavity, the temperature adjusting component comprises a heater and a refrigerator, and the temperature adjusting component is configured to adjust the temperature of the bearing surface;

the detection module comprises a temperature sensor, wherein the temperature sensor is used for acquiring data of temperatures of various parts of a user's body after the user lies on a bed, transmitting the data of the temperatures to the designating device, and the designating device is used for inquiring a preset corresponding relation between the temperatures and the postures to acquire posture data suitable for sleeping of the user according to the data of the temperatures, transmitting the posture data to the control assembly, and the control assembly adjusts the telescopic struts based on the posture data;

the detection module further comprises a pressure sensor, wherein the pressure sensor is used for collecting data of pressure applied to the pressure sensor by each part of a user body after the user lies on the bed, the data of the pressure is transmitted to the specification device, the specification device is used for inquiring a preset corresponding relation between the pressure and the posture according to the data of the pressure to obtain posture data suitable for sleeping of the user, the posture data is transmitted to the control assembly, and the control assembly adjusts the telescopic struts based on the posture data;

the smart bed further comprises: the temperature control component is connected with the control component, and when the temperature corresponding to the temperature data is smaller than a first specified temperature threshold, the control component controls the temperature control component to heat the bearing surface until the temperature corresponding to the temperature data is equal to the first specified temperature threshold, and when the temperature corresponding to the temperature data is larger than a second specified temperature threshold, the control component controls the temperature control component to cool the bearing surface until the temperature corresponding to the temperature data is equal to the second specified temperature threshold; the first specified temperature threshold is less than the second specified temperature threshold;

the outside of each spherical structure is respectively coated with a first film layer and a second film layer, at least one temperature sensor is arranged on the first film layer, and at least one pressure sensor is arranged on the second film layer;

the smart bed further comprises:

the first communication module is connected with the detection module and is configured to acquire data acquired by the detection module within a specified duration and transmit the acquired data to a specified device.

2. A method of controlling a smart bed, wherein the smart bed is the smart bed of claim 1, the method comprising:

acquiring a control instruction, wherein the control instruction is used for indicating the shape of a bearing surface of the intelligent bed, and the bearing surface is used for bearing a human body;

and controlling the telescopic struts to move based on the control instruction, so that the bearing surfaces of the telescopic struts are in the shapes indicated by the control instruction.

3. A smart bed system, comprising: the smart bed of claim 1, and a control device for controlling the smart bed.