KR102639440B1 - System for Providing Sleep Management by Using Stone Bed - Google Patents

Abstract

Launch of stone bed for sleep management.
This embodiment is equipped with a vital radar sensor inside the wooden frame of a stone bed to detect the vital state of the user on the stone mattress, and performs sleep management (sleep time, heart rate, tossing and turning) based on the vital state to display graphs or It provides a stone bed for sleep management that can be displayed in numerical form.

Description

Sleep management system using stone bed {System for Providing Sleep Management by Using Stone Bed}

One embodiment of the present invention relates to a sleep management system using a stone bed.

The content described below simply provides background information related to this embodiment and does not constitute prior art.

Typically, beds intended for sleeping are made of wood, synthetic resin, or metal with a mat frame and a mattress (mattress) with a built-in cushioning member such as a spring, or a mat with a built-in flat stone equipped with a heating means. etc. are being used.

The stone mat includes a mat frame in the form of a square box. The mat frame is made of an alloy of 85% nickel (Ni) and 15% chromium (Cr) on the upper surface, and a heating means made by attaching a nichrome wire used as a heating wire or resistance wire to a galvanium steel plate and foaming urethane foam is placed on it. It is constructed by covering copper plate and natural stone. For the mat frame, carbon heating film, a planar heating element, is attached to the top surface of the high pole, a type of Styrofoam, and then copper plates and copper nets are sequentially laid, and finally stones are placed on it.

The stone bed to which the above-mentioned general stone mat is applied first applies power to the heating means such as nichrome wire or carbon heating film, which is a planar heating element, and the heating element gradually generates heat, heating the natural stone to emit the desired temperature. The temperature of the stone mat is controlled so that it is warm in the winter and feels cool in the summer by stopping the operation of the heating means according to the characteristics of natural stone. The stone mat emits a certain amount of far-infrared rays from the additional ceramic, activating the human body's metabolism.

The present invention was created to solve the problems of the prior art as described above. The purpose of the present invention is to provide a vital radar sensor inside the wooden frame of a stone bed to detect the vital state of the user existing on the stone mattress, and to detect the vital state of the user on the stone mattress. The goal is to provide a sleep management system using a stone bed that performs sleep management (sleep time, heart rate, tossing and turning) based on the condition and displays it in a graph or numerical form.

According to one aspect of this embodiment, a water vein blocking sheet that is laid on the floor inside the wooden frame and blocks the water vein; A copper plate laminated on the water vein blocking sheet and blocking the water vein; a (third) heat insulating and shock absorbing cushioning agent applied in a laminated form on the copper plate to insulate and absorb shock; A special insulating sheet that is installed in a laminated form on the heat insulating and shock absorbing cushion to block electricity or heat; Heating means installed in a laminated form on the special insulating sheet to generate heat; A vital radar sensor that is stacked on or inserted into the heating means and collects vital data from the user; An electromagnetic wave blocking sheet that is installed in a stacked form on the heating means to block electromagnetic waves; A stone bed including a natural stone mattress installed in a stacked form on the electromagnetic wave blocking sheet; A user terminal that receives the vital data from the stone bed using a mounted sleep management application, analyzes the vital data, and provides sleep management for the user. .

As a preferred feature of the present invention, the natural stone mattress. It is configured to further include a weight detection unit that detects the user's weight when the user lies down, determines whether the user is using the bed, and applies a detection signal to the vital radar sensor connected to the output terminal to turn on the operation.

As described above, according to this embodiment, a vital radar sensor is provided inside the wooden frame of the stone bed to detect the vital state of the user present on the stone mattress, and sleep management (sleep time, heart rate, It has the effect of being able to present it in graph or numerical form by performing a toss and turn.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms or words used in this specification and claims should not be construed in their usual, dictionary meaning, and the inventor may appropriately define the concept of the term in order to explain his or her invention in the best way. It must be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is.

1 is a diagram showing a sleep management system according to this embodiment.
Figure 2 is a diagram showing the structure of the stone bed according to the first embodiment.
Figure 3 is a diagram showing public information fees according to the first embodiment.
Figure 4 is a diagram showing a copper plate according to the first embodiment.
Figure 5 is a diagram showing a special insulating sheet according to the first embodiment.
Figure 6 is a diagram showing a toy theory according to the first embodiment.
Figure 7 is a diagram showing an ultra-long wave coil according to the first embodiment.
Figure 8 is a diagram showing a toy theory according to the first embodiment.
Figure 9 is a diagram showing a copper plate according to the first embodiment.
Figure 10 is a diagram showing a heating floor according to the first embodiment.
Figure 11 is a diagram showing a heat insulating and shock absorbing cushioning agent according to the first embodiment.
Figure 12 is a diagram showing a special insulating sheet according to the first embodiment.
Figure 13 is a diagram showing a planar heating element according to the first embodiment.
Figure 14 is a diagram showing a controller according to the first embodiment.
Figure 15 is a diagram showing a vital radar sensor according to the first embodiment.
Figure 16 is a diagram showing an electromagnetic wave blocking sheet according to the first embodiment.
Figure 17 is a diagram showing a carbon nonwoven fabric according to the first embodiment.
Figure 18 is a diagram showing a natural stone mattress according to the first embodiment.
Figure 19 is a diagram showing the reinforcement of a stone bed according to the first embodiment.
Figure 20 is a diagram showing the structure of the stone bed according to the second embodiment.
Figure 21 is a diagram showing the reinforcement of a stone bed according to the second embodiment.
Figure 22 is a diagram showing radar sensor connection according to this embodiment.
Figure 23 is a diagram showing a sleep management application according to this embodiment.
Figure 24 is a diagram showing a charging confirmation pop-up according to this embodiment.
Figure 25 is a diagram showing measurement of a sleep management program according to this embodiment.
Figure 26 is a diagram showing date selection on a diary according to this embodiment.
Figure 27 is a diagram showing data in the diary in this embodiment.
Figure 28 is a diagram showing sleep management statistics in this embodiment.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail with reference to the attached drawings. However, it is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention. In this application, terms such as “include” or “have” are intended to designate the presence of features, steps, operations, components, parts, or combinations thereof described in the specification, but not one or more other features, steps, or operations. , it should be understood that it does not exclude in advance the possibility of the existence or addition of components, parts, or combinations thereof. In other words, throughout the specification, when a part is said to “include” a certain component, this means that it does not exclude other components but may further include other components, unless specifically stated to the contrary.

Additionally, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by those skilled in the art to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless clearly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

Here, repeated descriptions, known functions that may unnecessarily obscure the gist of the present invention, and detailed descriptions of configurations are omitted in order to not obscure the gist of the present invention. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

Hereinafter, this embodiment will be described in detail with reference to the attached drawings.

1 is a diagram showing a sleep management system according to this embodiment.

The sleep management system according to this embodiment includes a user terminal 110, a sleep management application 112, and a stone bed 120. Components included in the sleep management system are not necessarily limited to this.

The user terminal 110 refers to an electronic device that performs data communication with the stone bed 120 using short-distance communication according to the user's key operations.

The user terminal 110 includes a memory for storing a program or protocol for communicating with the stone bed 120 using short-distance communication, and a microprocessor for executing the program to operate and control the program.

The user terminal 110 includes a smart phone, tablet, laptop, personal computer (PC), personal digital assistant (PDA), and portable multimedia player (PMP). It may be an electronic device such as a multimedia player, a wireless communication terminal, or a media player.

The user terminal 110 may perform short-distance communication with the stone bed 120 using the sleep management application 112 mounted on the storage to perform sleep management for the user. The user terminal 110 connects to the stone bed 120 using the sleep management application 112.

The sleep management application 112 refers to a program mounted and run in the storage of the user terminal 110. The sleep management application 112 may be mounted on the user terminal 110 in an embedded form or installed on an operating system (OS).

If the user terminal 110 is a smart phone, the sleep management application 112 can be downloaded and installed using the application store. The sleep management application 112 may operate in conjunction with applications already installed in the user terminal 110. The sleep management application 112 is operated by the user's operation or command of the user terminal 110.

The sleep management application 112 receives vital data from the stone bed 120. The sleep management application 112 analyzes vital data and provides sleep management for the user. The sleep management application 112 analyzes vital data to determine the user's heart rate, breathing rate, and tossing and turning while sleeping. The sleep management application 112 provides sleep management based on heart rate, breathing rate, and tossing and turning.

The stone bed 120 is equipped with a memory for storing a program or protocol for communicating with the user terminal 110 using short-distance communication, and a microprocessor for executing the program to operate and control the program.

The stone bed 120 is equipped with various devices such as communication devices such as a communication modem for communicating with various devices or wired and wireless networks, memory for storing various programs and data, and a microprocessor for calculating and controlling the program by executing it. It is a device. According to at least one embodiment, the memory is computer memory such as random access memory (RAM), read only memory (ROM), flash memory, optical disk, magnetic disk, and solid state disk (SSD). It may be a readable recording/storage medium. According to at least one embodiment, a microprocessor may be programmed to selectively perform one or more of the operations and functions described in the specification. According to at least one embodiment, a microprocessor may be implemented in whole or in part as hardware such as an application specific integrated circuit (ASIC) of a specific configuration.

The stone bed 120 refers to a bed including a natural stone mattress 1810 rather than a spring-type mattress. A natural stone mattress (1810) is placed on the surface of the bed. The stone bed 120 communicates with the user terminal 110 using short-distance communication (eg, Bluetooth). The stone bed 120 collects the user's vital data existing on the natural stone mattress 1810 using the vital radar sensor 1530.

The stone bed 120 operates in conjunction with the sleep management application 112. The stone bed 120 transmits the sensed vital data (heart rate, breathing rate, sleep time) to the sleep management application 112 using the vital radar sensor 1530. The stone bed 120 operates the vital radar sensor 1530 using ultra-long waves independently of controlling the temperature of the stones. The stone bed 120 transmits vital data including heart rate, breathing rate, and sleep time to the sleep management application 112 while operating the vital radar sensor 1530.

The stone bed 120 senses vital data (heart rate, breathing rate, sleep time) during a preset sleep time, maps it by date, and stores it. The sleep management application 112 checks vital data (heart rate, breathing rate, sleep time) mapped by date by user's operation or command.

When the stone bed 120 recognizes that there is no person on the natural stone mattress 1810, it displays it as absent. When there are multiple users around, the stone bed 120 selects one user based on the largest value among the signals received using the vital radar sensor 1530, and vital data (heart rate, Respiratory rate, sleep time) are displayed.

When a user sleeps on the natural stone mattress 1810, the stone bed 120 generally scans the user's body and calculates a sleep score based on vital data. When the stone bed 120 senses the heart rate based on the vital radar sensor 1530, it sets an initial value based on preset data. The stone bed 120 displays the date on which sleep information (sleep time, heart rate, degree of tossing and turning) was measured each month on the calendar. The stone bed 120 determines that an actual valid value is measured only when the vital data collected from the vital radar sensor 1530 is slept in the bed for more than a preset threshold time.

When bedtime and wake-up time are set with the sleep management application 112, the stone bed 120 continuously senses vital data during that time. The stone bed 120 calculates heart rate, sleep efficiency, sleep score, tossing and turning index, and breathing disorder index based on vital data. The stone bed 120 allows the user to manage sleep by scanning the body while sleeping on the natural stone mattress 1810. The stone bed 120 outputs sleep management information to the sleep management application 112 mounted on the user terminal 110 or outputs it from the screen of the controller 1410 itself.

Figure 2 is a diagram showing the structure of the stone bed according to the first embodiment.

The stone bed 120 according to the first embodiment includes a water vein blocking sheet 202, a wooden frame 310, a high-elastic cushioning material 206, leather 208, an ultra-long wave mounting frame 320, a copper plate 910, 3 Insulation and shock absorption cushion (1110), second special insulation sheet (1210), planar heating element (1310), heating floor (1010), temperature overload detection sensor (1520), temperature detection sensor (1510), It includes an electromagnetic wave blocking sheet (1610), a carbon non-woven fabric (1710), a vital radar sensor (1530), and a natural stone mattress (1810). Components included in the stone bed 120 according to the first embodiment are not necessarily limited thereto.

The ultra-long wave mounting frame 320 and the ultra-long wave coil 710 installed on the stone bed 120 according to the first embodiment can be implemented selectively.

Figure 3 is a diagram showing public information fees according to the first embodiment.

The cost of the stone bed 120 includes a wooden frame 310. Before assembly, the wooden frame 310 is covered with a high-elasticity cushioning agent 206 and then covered with leather 208. The edges of the wooden frame (310) in its pre-assembly form are covered with high-elasticity cushioning (206) and leather (208).

A water vein blocking sheet (202) is laid on the floor inside the wooden frame (310) of the stone bed (120). The ultra-long wave mounting frame 320 is stacked on the water vein blocking sheet 202 on the inner bottom surface of the wooden frame 310. Here, the water vein blocking sheet 202 blocks the water vein waves.

The water vein blocking sheet 202 is laid on the floor inside the wooden frame 310 and blocks the water vein. The ultra-long wave mounting frame 320 includes a plurality of grooves 330 for embedding the ultra-long wave coil 710.

A plurality of rail-shaped grooves 330 are formed in the ultra-long wave mounting frame 320. A plurality of grooves 330 are formed in a rail shape inside the ultra-long wave mounting frame 320. When the stone bed is for one person, two plurality of grooves 330 may be formed so that the single user can cover the entire body when lying down.

When the stone bed is for two people, the plurality of grooves 330 are preferably formed on the left or right side of the center so that they can cover only one person, but this is not necessarily limited.

When the stone bed is for two people, four grooves 330 may be formed on the left and right sides to cover all two people. The plurality of grooves 330 may be connected to a power source so that one side is connected to a plus side and the other side is connected to a minus side.

Figure 4 is a diagram showing a copper plate according to the first embodiment.

A copper plate 410 is taped to the bottom of the groove 330 of the ultra-long wave mounting frame 320. In other words, the copper plate 410 is adhered to the bottom of each of the plurality of grooves 330. Before embedding the ultra-long wave coil 710 in the groove 330 of the ultra-long wave mounting frame 320, the copper plate 410 is attached with tape to block the water vein.

Figure 5 is a diagram showing a special insulating sheet according to the first embodiment.

After taping the copper plate 410 to the bottom of the groove 330 of the ultra-long wave mounting frame 320, the first special insulating sheet 510 in the form of a translucent sheet is attached. When the first special insulating sheet 510 is attached on the copper plate 410 in the groove 330, it prevents electricity or heat from conducting. After the copper plate 410 is adhered to the bottom of each of the plurality of grooves 330, the first special insulating sheet 510 in a translucent form is laminated.

Figure 6 is a diagram showing a toy theory according to the first embodiment.

Before attaching the ultra-long wave coil 710 on the first special insulating sheet 510 in the groove 330 of the ultra-long wave mounting frame 320, a first insulating and shock-absorbing cushioning agent ( 610) is attached. A first insulating and shock absorbing cushioning agent 610 is laminated on the first special insulating sheet 510.

The first insulating and shock absorbing cushion 610 is installed on the floor of the ultra-long wave coil 710 embedded in the groove 330, and protects the ultra-long wave coil 710 from shock coming from the floor.

Figure 7 is a diagram showing an ultra-long wave coil according to the first embodiment.

The ultra-long wave coil 710 is attached onto the first insulating and shock-absorbing cushioning material 610 in the groove 330 of the ultra-long wave mounting frame 320.

The ultra-long wave coil 710 is inserted into the plurality of grooves 330 onto the first heat insulating and shock absorbing cushioning material 610. A preset number of ultra-long wave coils 710 can be inserted into each of the plurality of grooves 330 . Preferably, 10 ultra-long wave coils 710 are embedded in the groove 330. Five ultra-long wave coils 710 may be embedded in each groove 330 . It is preferable that five ultra-long wave coils 710 are inserted into each groove 330, but this is not necessarily limited.

The ultra-long wave coil 710 generates ultra-long waves. The ultra-long wave coil 710 is installed on the first insulating and shock-absorbing cushioning material 610 in the groove 330. The ultra-long wave coil 710 is installed on the first insulating and shock-absorbing cushion 610 in the groove 330 in a laid state.

The very-long wave coil 710 outputs a very-low-frequency wave (VLF) between 3 and 30 KHz, the lowest among radio frequencies. Ultra-long waves refer to natural magnetic waves that occur when the N and S poles change at very high speeds 5 to 60 times per second. The ultra-long wave coil (710) radiates a wavelength of 5 to 6 million meters into the human body, penetrating into internal organs, blood vessels, and nerves in the bone marrow, vibrating human cells to promote endocrine function, and cleaning impurities such as cholesterol in the blood, improving blood circulation. It improves and also helps relieve pain.

The ultra-long wave coil 710 radiates ultra-long waves (wavelength of 5 to 6 million m) to the human body to help relieve muscle pain, and as it penetrates each part of the human body, it relieves coagulated muscles throughout the body and removes carbon, nitrogen, and manganese from the human body. , helps magnetize iron, etc., stimulates cells in the body, unclogs blood vessels, and restores health.

The ultra-long wave coil 710 radiates ultra-long waves to the human body during sleep so that health can be improved just by sleeping.

When the ultra-long wave coil 710 radiates ultra-long waves to the human body, the stone bed 120 according to this embodiment removes harmful electromagnetic waves harmful to the human body due to the electromagnetic wave blocking sheet 1610 installed at the bottom of the natural stone mattress 1810 and provides beneficial effects. Only allow electromagnetic waves to be received. The ultra-long wave coil 710 protects the human body from electromagnetic waves by applying the M-Free system, which converts power to direct current and supplies current. In the case of a two-person bed, the ultra-long wave coil 710 exists only in the space used by one person, and only the heating function can be used in the area where the ultra-long wave coil 710 does not exist in the space used by the other person. In the case of a two-person bed, the stone bed 120 can optionally be implemented to have both an ultra-long wave coil 710 and a heating function installed inside the natural stone mattress 1810, or to have only a heating function.

When the stone bed 120 only implements a heating function, there is no need to form the groove 330 and bury the ultra-long wave coil 710.

On the other hand, the natural stone mattress (1810) in the present invention. It may also be implemented with a configuration that includes a weight sensing unit (not shown) to detect the user's weight when the user lies down and determine whether the user is using the bed. This means that if the vital radar sensor 1530 maintains the always-on operation state, it remains in a detection standby state even when the user does not use the bed. In the case of the sensor, the longer the use time, the higher the failure rate. It only needs to work when the user is lying in bed.

Accordingly, the present invention additionally configures a weight sensing unit made of a load cell that is easy to apply, inexpensive, and has relatively high detection reliability, and provides load information detected when the user makes a motion to lie down on the bed, and information based on tossing and turning during the lying down process. As an example, it is proposed that when the set value is met using the weight change as detection information, a detection signal is applied to the vital radar sensor 1530 connected to the output terminal to turn on the operation of the vital radar sensor 1530. do.

For example, assuming a user weighing 70kg lies down on a bed, when the user gets on the bed, a weight sensing unit made of a load cell measures the load. At this time, the user moves for a certain period of time to lie down, so the user feels the weight. The weight detection value of the branch also changes frequently for a certain period of time.

Subsequently, the fluctuating value of the user's body weight (weight) detected by the weight sensing unit decreases, and when the weight change value stabilizes and detects 70Kg, it is determined that the user has maintained the lying posture, and the A signal is applied, and the weight sensing unit ends detection.

The weight sensing unit detects the weight generated when the user moves to lie down. If the weight change value measured for a certain period of time after starting the weight detection falls within the preset range (0 to 10 kg), it determines that the user is ready for bed. , the operation is turned on by applying a detection signal to the vital radar sensor connected to the output terminal.

Figure 8 is a diagram showing a toy theory according to the first embodiment.

After attaching the ultra-long wave coil 710 onto the first insulating and shock-absorbing cushion 610 in the groove 330 of the ultra-long wave mounting frame 320, the ultra-long wave coil 710 is placed on top of the ultra-long wave coil 710 to protect the ultra-long wave coil 710 from shock. A second heat insulating and shock absorbing cushioning material 810 is attached.

In order to protect the ultra-long wave coil 710, a second insulating and shock-absorbing cushioning agent 810 is laminated on the ultra-long wave coil 710.

Figure 9 is a diagram showing a copper plate according to the first embodiment.

The copper plate 910 is attached to the ultra-long wave mounting frame 320 except for the area where the second insulating and shock-absorbing cushioning material 810 is attached. The copper plate 910 is attached to the remaining portion except the groove 330 where the ultra-long wave coil 710 for blocking the water vein is attached.

The copper plate 910 is attached to areas other than the plurality of grooves 330 in the ultra-long wave mounting frame 320 into which the ultra-long wave coil 710 is inserted. Here, the copper plate 910 refers to a 99.9% pure copper plate. Since the ultra-long wave coil 710 was inserted into the plurality of grooves 330 with the copper plate 410 for blocking the water vein taped to the bottom in advance, the remaining portion of the ultra-long wave mounting frame 320 excluding the plurality of grooves 330 Cover the copper plate 910.

After laying the copper plate 410 in the form of a tape on the bottom surface of the plurality of grooves 330 and placing the ultra-long wave coil 710 on it, a cushioning agent is applied to the ultra-long wave coil 710, and the remaining area excluding the area where the ultra-long wave coil 710 exists is applied. The copper plate 910 is installed again in the area.

In the process of installing the copper plate on all surfaces in a plane, the copper plate 410 is installed in the form of a tape on the bottom of the groove 330 where the ultra-long wave coil 710 is installed, and the copper plate (410) is installed on the upper part where the ultra-long wave coil 710 is installed. 910) is not installed.

When the ultra-long wave mounting frame 320 is not installed, the copper plate 910 is laminated on the water vein blocking sheet 202 and blocks the water vein. When attaching the copper plate 910, the copper plate is attached only to the remaining area, excluding the area where the ultra-long wave coil 710 embedded in the plurality of grooves 330 formed in the ultra-long wave mounting frame 320 exists.

Figure 10 is a diagram showing a heating floor according to the first embodiment.

A heating floor (1010) made of wood is installed at the edges and center on the copper plate (910) inside the wood frame (310).

The heating floor 1010 does not heat the planar heating element 1310 in close contact with the natural stone mattress 1810, but heats the natural stone mattress 1810 by forming a 20 mm air layer due to the heating floor 1010.

A heating floor 1010 made of wood is installed on the copper plate 910 with a step of about 20 mm to prevent the planar heating element 1310 from coming into close contact with the natural stone mattress 1810.

Due to the heating floor 1010 made of wood, the copper plate 910 is not in direct contact with the planar heating element 1310 and has a step of about 20 mm. The heating floor 1010 is first installed at the edges and center of the inside of the wooden frame 310.

The heating floor 1010 refers to the space formed between the copper plate 910 and the electromagnetic wave blocking sheet 1610. A third insulating and shock absorbing cushion 1110, a second special insulating sheet 1210, a planar heating element 1310, and a vital radar sensor 1530 are disposed in the space formed by the heating floor 1010. The heating floor 1010 secures a space of approximately 20 mm between the planar heating element 1310 and the electromagnetic wave blocking sheet 1610. The heating floor 1010 allows the heat generated from the planar heating element 1310 to heat the air, thereby raising the temperature of the natural stone mattress 1810 located at the top.

When the heating means is a film-type planar heating element 1310, the heating floor 1010 is installed at the edge and center on the copper plate 910 inside the wooden frame 310 to secure a space spaced apart by a preset distance.

The heating floor 1010 secures a space spaced apart from the copper plate 910 and the electromagnetic wave blocking sheet 1610 by a preset distance. A third insulating and shock absorbing cushion 1110, a second special insulating sheet 1210, a heating means, and a vital radar sensor 1530 are placed in the space separated by the heating floor 1010.

The heating floor 1010 uses a space spaced apart by a preset distance between the copper plate 910 and the electromagnetic wave blocking sheet 1610, and the heat generated from the heating means warms the air layer, thereby increasing the temperature of the natural stone mattress 1810 located at the top. Let's raise it.

Figure 11 is a diagram showing a heat insulating and shock absorbing cushioning agent according to the first embodiment.

A third heat insulating and shock absorbing cushion 1110 is installed between the heating floor 1010 installed at the edge and the center on the copper plate 910 inside the wooden frame 310. The third heat insulating and shock absorbing cushion 1110 prevents the heat generated by the planar heating element 1310 from being directed to the floor and absorbs shock. The third heat insulating and shock absorbing cushioning agent 1110 is applied in a laminated form on the copper plate 910 to insulate and absorb shock.

A third heat insulating and shock absorbing cushion 1110 is installed in the internal space where the heating floor 1010 is installed. In other words, since the heating floor 1010 is installed only at the inner edge and center of the wooden frame 310, the third insulation and shock absorbing cushion 1110 is installed in the space where the heating floor 1010 is not installed.

Figure 12 is a diagram showing a special insulating sheet according to the first embodiment.

After installing the third insulating and shock absorbing cushioning material 1110 between the edge and the heating floor 1010 installed in the center on the copper plate 910 inside the wooden frame 310, a second special insulating sheet (in the form of a translucent sheet) 1210) is installed.

The second special insulating sheet 1210 is attached on the third insulating and shock absorbing cushion 1110 to prevent electricity or heat from passing through. The second special insulating sheet 1210 is installed in a laminated form on the third insulating and shock absorbing cushion 1110 to block electricity or heat.

A second special insulating sheet 1210 is laminated on the third insulating and shock absorbing cushion 1110. In other words, the second special insulating sheet 1210 is laminated on the third insulating and shock absorbing cushion 1110 installed in the internal space where the heating floor 1010 is installed.

Figure 13 is a diagram showing a planar heating element according to the first embodiment.

After installing the third insulation and shock absorbing cushion 1110 and the second special insulation sheet 1210 on the copper plate 910 inside the wooden frame 310, a heating floor 1010 is added to separate a plurality of areas. Install.

A planar heating element (1310) is installed between the heating floors (1010) divided into each area. The planar heating element 1310 refers to a heating element in the form of a flexible film rather than a heating panel. The heating means (planar heating element 1310) is installed in a stacked form on the second special insulating sheet 1210 to generate heat.

The heating floor 1010 is additionally installed to separate the area where the planar heating element 1310 is installed between the edge and the center. The planar heating element 1310 is stacked on the second special insulating sheet 1210. A planar heating element 1310 is installed on the second special insulating sheet 1210 installed in the internal space where the heating floor 1010 is installed.

The planar heating element 1310 heats the air in the upper layer using the heating floor 1010, and raises the temperature of the natural stone mattress 1810 with the warmed air.

The planar heating element 1310 can raise the temperature of the air layer of the heating floor 1010 to 70°C, and the temperature of the natural stone mattress 1810 can be raised to 50°C using the air layer caused by the heating floor 1010.

Figure 14 is a diagram showing a controller according to the first embodiment.

The controller 1410 is installed on one side of the wooden frame 310. The controller 1410 is preferably installed on the user's head, but is not necessarily limited to this. The controller 1410 provides the ability to turn on/off the power of the stone bed, control temperature, and select whether to use ultra-long waves.

Controller 1410 supplies power. The controller 1410 is installed outside, and heart rate and tossing and turning information can be displayed as numbers on the controller 1410.

The controller 1410 is connected to the planar heating element 1310, the microwave coil 710, the vital radar sensor 1530, the temperature detection sensor 1510, and the temperature overheating detection sensor 1520, respectively. When the stone bed 120 is for two people, two controllers 1410 may be installed on the upper side of the wooden frame 310. When the stone bed 120 is for one person, only one controller 1410 can be installed on the upper side of the wooden frame 310.

The controller 1410 is installed on one side of the wooden frame 310. The controller 1410 is connected to a heating means, a microwave coil 710, a vital radar sensor 1530, a temperature sensor 1510, and an overtemperature detection sensor 1520, respectively. The controller 1410 provides functions to turn on/off the power of the stone bed, control the temperature of the heating means, and select whether or not to generate ultra-long waves for the ultra-long wave coil.

The controller 1410 outputs vital data collected from the vital radar sensor 1530 on its own screen.

The controller 1410 transmits vital data collected from the vital radar sensor 1530 to the user terminal 110 using short-range communication. The controller 1410 controls each of the vital radar sensor 1530, the heating means, the ultra-long wave coil 710, the vital radar sensor 1530, the temperature detection sensor 1510, and the excessive temperature detection sensor 1520.

Figure 15 is a diagram showing a vital radar sensor according to the first embodiment.

After installing the planar heating element 1310 between the heating floors 1010 divided for each area, a vital radar sensor 1530, a temperature detection sensor 1510, and an excessive temperature detection sensor 1520 are installed. The vital radar sensor 1530 is preferably installed in an area where there is no microwave coil 710. The vital radar sensor 1530 is preferably installed at a location corresponding to the area where the user's heart is located when the user lies down on the stone bed 120.

The temperature sensor 1510 is laminated on or inserted into the heating means and detects the temperature generated by the heating means. The temperature overheating detection sensor 1520 is stacked on or inserted into the heating means to prevent the heating means from overheating above a preset temperature. The vital radar sensor 1530 is stacked on a heating means (planar heating element 1310) or inserted into a heating means (thermal panel 2100) to collect vital data from the user.

It is preferable that one vital radar sensor 1530 is mounted within the inner frame of the bed, but it is not necessarily limited to this, and multiple sensors can be added. A plurality of vital radar sensors 1530 can be used in a double bed. The vital radar sensor 1530 measures distance and speed using a radar method. The vital radar sensor 1530 can determine the location, distance, speed, direction, etc. of the user on the natural stone mattress 1810.

The vital radar sensor 1530 may be attached to the planar heating element 1310 or inserted into the heat panel 2100. When the vital radar sensor 1530 is attached to the planar heating element 1310, it can be attached directly on the planar heating element 1310. When the vital radar sensor 1530 is inserted into the thermal panel 2100, the vital radar sensor 1530 can be mounted after cutting a part of the thermal panel 2100.

The vital radar sensor 1530 is installed in the internal space resulting from the installation of the heating floor 1010. The vital radar sensor 1530 is inserted into the space caused by the installation of the heating floor 1010 between the planar heating element 1310 and the electromagnetic wave blocking sheet 1610.

The vital radar sensor 1530 can be installed in any one of the areas where the heating floor 1010 is divided by connecting the edge and the center. A plurality of vital radar sensors 1530 may be installed in a plurality of areas among the areas divided by the heating floor 1010 connecting the edge and the center.

The vital radar sensor 1530 is preferably placed in an area where the ultra-long wave coil 710 is not installed. The vital radar sensor 1530 is preferably placed at a position corresponding to the area where the user's heart is located when the user lies down on the natural stone mattress 1810.

Vital Radar Sensor (1530) refers to a non-contact radar sensor that detects the user's biosignals such as heartbeat and breathing. The vital radar sensor 1530 transmits the measured vital data to the sleep management application 112. The sleep management application 112 monitors the individual's sleep health by analyzing vital data received from the vital radar sensor 1530. The vital radar sensor 1530 is ultra-small and low-power and can be attached on the planar heating element 1310 or embedded inside the heat panel 2100. The vital radar sensor 1530 can measure in a non-contact manner without being attached to the human body. The vital radar sensor 1530 transmits radar to the user's heart and detects heartbeat, breathing, and movement based on the reflected signal reflected in response to the radar.

The vital radar sensor 1530 uses radar technology to detect vital signals such as heart rate and breathing rate from a distance. The vital radar sensor 1530 emits a low-power microwave signal (radar signal) to the human body and measures a reflected signal reflected from the human body in response to the low-power microwave signal (radar signal).

The vital radar sensor 1530 uses low-power microwave signals (radar signals) to transmit vibrations from heart movement or blood pulse to the skin, and detects heartbeat by measuring the Doppler effect of these minute movements. The vital radar sensor 1530 uses low-power microwave signals (radar signals) to detect breathing. When breathing, the diaphragm of the chest moves due to the movement of the lungs, and it detects breathing by measuring the Doppler effect of the diaphragm. The vital radar sensor 1530 analyzes reflected signals (radar signals) to determine a person's heart rate, respiratory rate, and other vital signs.

The vital radar sensor 1530 is non-contact, so it does not require physical contact with the body and monitors patients in real time from a distance. The vital radar sensor 1530 continuously monitors the state of the sleeping user.

The vital radar sensor 1530 emits a low-power microwave signal to the human skin and receives a reflected signal that reflects in response to the low-power microwave signal. The vital radar sensor 1530 generates vital data including the results of measuring the blood pulse, heart movement, and vibration caused by the diaphragm movement using the Doppler effect based on the reflected signal.

The vital radar sensor 1530 emits low-power microwave signals (radar signals) to the skin of the chest area and receives reflected signals reflected from the skin. The vital radar sensor 1530 measures the heartbeat from a reflected signal using the Doppler effect generated by vibration of the human skin due to blood, heartbeat, and movement of the diaphragm.

Figure 16 is a diagram showing an electromagnetic wave blocking sheet according to the first embodiment.

After installing the heating floor (1010) on the copper plate (910) inside the wooden frame (310), a third insulating and shock absorbing cushion (1110) and a second special insulating sheet (1210) are placed in the space created by the heating floor (1010). ), install the planar heating element (1310). An electromagnetic wave blocking sheet (1610) is installed on the planar heating element (1310) to cover the entire heating floor (1010). The electromagnetic wave blocking sheet 1610 is stacked to cover the entire heating floor 1010.

The electromagnetic wave blocking sheet 1610 serves as a shielding sheet that blocks electromagnetic waves. The electromagnetic wave blocking sheet 1610 is installed in a stacked form on top of the heating means to block electromagnetic waves.

Figure 17 is a diagram showing a carbon nonwoven fabric according to the first embodiment.

The material is completed by covering the carbon non-woven fabric (1710) on the electromagnetic wave blocking sheet (1610) and performing the finishing work. Carbon nonwoven fabric 1710 is laminated in a way that covers the entire electromagnetic wave blocking sheet 1610.

Figure 18 is a diagram showing a natural stone mattress according to the first embodiment.

The stone bed 120 is completed by attaching the natural stone mattress 1810 on the carbon nonwoven fabric 1710. A natural stone mattress (1810) is installed to cover the entire carbon non-woven fabric (1710). In the case of a double bed, two natural stone mattresses (1810) are installed on the left and right sides. In the case of a single bed, one natural stone mattress (1810) is stacked.

The natural stone mattress 1810 is installed in a stacked form on the electromagnetic wave blocking sheet 1610.

Figure 19 is a diagram showing the reinforcement of a stone bed according to the first embodiment.

A water vein blocking sheet (202) is installed inside the wooden frame (310) of the stone bed (120). Install the ultra-long wave mounting frame (320) on the water vein blocking sheet (202). A copper plate 910, a first special insulating sheet 510, and a first insulating and shock absorbing cushion 610 are installed in the groove 330 formed in the ultra-long wave mounting frame 320.

The ultra-long wave coil 710 is embedded on the first insulating and shock-absorbing cushion 610 inside the groove 330 formed in the ultra-long wave mounting frame 320, and then the first insulating and shock-absorbing cushion 610 is attached. A copper plate 910 is installed on the ultra-long wave mounting frame 320 to cover the remaining area where the ultra-long wave coil 710 is not installed.

The ultra-long wave mounting frame 320 is laminated on the water vein blocking sheet 202 on the inner bottom surface of the wooden frame 310. The copper plate is attached to the bottom of the plurality of grooves 330 formed in the ultra-long wave mounting frame 320.

The first special insulating sheet 510 is laminated on the copper plate 410 adhered to the bottom of the groove 330 to block electricity or heat. The first insulating and shock absorbing cushion 610 is laminated on the first special insulating sheet in the groove 330 to protect against shock coming from the floor.

The ultra-long wave coil 710 is installed on the first insulating and shock-absorbing cushioning material in the groove 330. The second heat insulating and shock absorbing cushion 810 is laminated on the ultra long wave coil 710 in the groove 330 to protect the ultra long wave coil 710 from impact.

A heating floor 1010 with a 20 mm step is installed between the copper plate 910 and the electromagnetic wave blocking sheet 1610. A third insulating and shock absorbing cushion 1110, a second special insulating sheet 1210, and a planar heating element 1310 are installed in the space created by the heating floor 1010. A vital radar sensor 1530 is installed on the planar heating element 1310.

The vital radar sensor 1530 is installed at a location corresponding to the area where the user's heart is located when the user lies down on the natural stone mattress 1810. An electromagnetic wave blocking sheet (1610), a carbon non-woven fabric (1710), and a natural stone mattress (1810) are installed on the planar heating element (1310).

Figure 20 is a diagram showing the structure of the stone bed according to the second embodiment.

The stone bed 120 according to the second embodiment includes a water vein blocking sheet 202, a wooden frame 310, a high-elastic cushioning material 206, leather 208, an ultra-long wave mounting frame 320, a copper plate 910, 3 Insulation and shock absorption cushion (1110), second special insulation sheet (1210), thermal panel (2100), heating floor (1010), temperature overheating detection sensor (1520), temperature detection sensor (1510), electromagnetic wave blocking sheet ( 1610), carbon non-woven fabric (1710), vital radar sensor (1530), and natural stone mattress (1810). Components included in the stone bed 120 according to the first embodiment are not necessarily limited thereto.

The ultra-long wave mounting frame 320 and the ultra-long wave coil 710 installed on the stone bed 120 according to the second embodiment can be implemented selectively.

The heat panel 2100 is a panel made of aluminum or galbanium, and includes a heat wire and special insulating urethane (2012) inside. Heating wires include nichrome heating wire (2002), silicon (2004), zero-wave copper wire (2006), and far-infrared radiation silicon (2008).

The thermal panel 2100 is equipped with a vital radar sensor 1530 therein. In order to mount the vital radar sensor 1530, a hole is drilled on one side of the thermal panel 2100 to form a space, and then the vital radar sensor 1530 is placed.

The thermal panel 2100 is directly connected to the natural stone mattress 1810, and the heat generated from the thermal panel 2100 heats the natural stone mattress 1810, causing the temperature of the natural stone mattress 1810 to rise. The heat panel (2100) is a method of installing a steel plate made of aluminum or galvanized material instead of the planar heating element (1310) and placing a natural stone mattress (1810) on the steel plate. Since the heat panel 2100 has no space due to the heating floor 1010, the vital radar sensor 1530 is placed by drilling through one side of the heat panel 2100.

In the thermal panel 2100, a hole is drilled at a position corresponding to the user's heart position, a vital radar sensor 1530 is placed at the corresponding position, and a finishing process (adhesion process) is performed.

Since the thickness of the thermal panel 2100 is approximately 20 mm, the vital radar sensor 1530 can be placed. The heat panel 2100 includes a heat wire and urethane foam inside. The heating wire uses nichrome heating wire (2002), silicon (2004), zero wave copper net (2006), and far-infrared radiation silicon (2008) to prevent the vital radar sensor 1530 from being affected by heat.

Figure 21 is a diagram showing the reinforcement of a stone bed according to the second embodiment.

A water vein blocking sheet (202) is installed inside the wooden frame (310) of the stone bed (120). Install the ultra-long wave mounting frame (320) on the water vein blocking sheet (202). A copper plate 910, a first special insulating sheet 510, and a first insulating and shock absorbing cushion 610 are installed in the groove 330 formed in the ultra-long wave mounting frame 320.

The ultra-long wave coil 710 is embedded on the first insulating and shock-absorbing cushion 610 inside the groove 330 formed in the ultra-long wave mounting frame 320, and then the first insulating and shock-absorbing cushion 610 is attached. A copper plate 910 is installed on the ultra-long wave mounting frame 320 to cover the remaining area where the ultra-long wave coil 710 is not installed. A third insulating and shock absorbing cushion 1110 and a second special insulating sheet 1210 are installed on the copper plate 910. A thermal panel 2100 is installed on the second special insulating sheet 1210.

When the heating means is a heat panel 2100, a hole is drilled on one side of the heat panel 2100 to form an empty space, and then the vital radar sensor 1530 is placed in the empty space. The heat panel 2100 has a plurality of heat wires disposed inside, and the spaces between the plurality of heat wires are filled with special insulating urethane (2012).

Heat wires include nichrome heat wire (2002), silicon (2004), zero wave copper wire (2006), and radiant silicon (2004). Nichrome heating element (2002) generates heat. Silicone (2004) has the form of a covering surrounding the outside of the nichrome heating wire (2002). The zero-wave network (2006) has a shape that surrounds the entire exterior of the silicon (2004). Far-infrared ray-emitting silicon (2008) has the form of a covering surrounding the outside of the zero-wave network (2006).

An electromagnetic wave blocking sheet (1610), a carbon non-woven fabric (1710), and a natural stone mattress (1810) are installed on the thermal panel (2100). The heat panel 2100 directly heats the natural stone mattress 1810 using internal heating wires without passing through an air layer.

Figure 22 is a diagram showing radar sensor connection according to this embodiment.

The user terminal 110 connects to the vital radar sensor 1530 of the stone bed 120 through short-distance communication using the sleep management application 112. The user terminal 110 uses the sleep management application 112 to scan the body condition of the user lying on the stone bed 120 at a preset time. The user terminal 110 uses the sleep management application 112 to periodically receive vital data obtained by scanning the user's body condition through short-distance communication from the stone bed 120.

Figure 23 is a diagram showing a sleep management application according to this embodiment.

The user terminal 110 uses the sleep management application 112 to output ‘wake-up time’, ‘heart rate’, and ‘respiratory rate’ on the initial screen.

When the user terminal 110 is connected to the stone bed 120 through short-distance communication using the sleep management application 112, 'heart rate' and 'respiratory rate' are calculated based on vital data received from the vital radar sensor 1530. and print it on the screen.

If the user terminal 110 does not want to measure ‘heart rate’ and ‘respiration rate’ using the sleep management application 112, turn it off in the settings. The user terminal 110 performs sleep measurement when there is an input to the sleep start button on the sleep management application 112.

The user terminal 110 outputs ‘wake-up time’ and ‘bedtime’ on the sleep management application 112. The user terminal 110 displays the title ‘wake up time’ on the sleep management application 112. The user terminal 110 applies the time set in the profile, etc. as ‘bedtime’ on the sleep management application 112.

The user terminal 110 displays the user's absence, heart rate, and movement on the stone bed 120 on the sleep management application 112. If the state on the sleep management application 112 is 0, the user terminal 110 displays “absence”. The user terminal 110 displays “heart rate and breathing rate” when the state is 1 to 3 on the sleep management application 112. The user terminal 110 displays “movement” when the state is 4 on the sleep management application 112.

Figure 24 is a diagram showing a charging confirmation pop-up according to this embodiment.

The user terminal 110 displays a pop-up on the sleep management application 112 to maintain the charging state before starting sleep. When the confirmation button for the maintenance of charging state before sleep start pop-up is input on the sleep management application 112, the user terminal 110 recognizes sleep as starting. When ‘Do not view again’ is checked on the sleep management application 112, the user terminal 110 prevents the pop-up to maintain charging status before sleep from being displayed from next time.

Figure 25 is a diagram showing measurement of a sleep management program according to this embodiment.

The user terminal 110 displays the current time and alarm time on the sleep management application 112. The user terminal 110 displays the ‘sleep time’, ‘heart rate’, and ‘respiratory rate’ being measured on the sleep management application 112. The user terminal 110 displays the possibility of stopping measurement by ‘sliding upward’ on the screen on the sleep management application 112.

Figure 26 is a diagram showing date selection on a diary according to this embodiment.

The user terminal 110 records and confirms the date on which vital data was measured during sleep on the sleep management application 112 on the calendar. The user terminal 110 selects a specific date from the calendar on the sleep management application 112 to store or check vital data.

Figure 27 is a diagram showing data in the diary in this embodiment.

The user terminal 110 checks heart rate and respiratory rate statistics on the sleep management application 112. The user terminal 110 displays the average, minimum, and maximum values of heart rate and respiratory rate, respectively, on the sleep management application 112. The user terminal 110 displays a minimum bar graph and a maximum bar graph for each time period on the sleep management application 112. The user terminal 110 outputs the highest and lowest time zones on the sleep management application 112 with emphasis. The user terminal 110 displays tossing and turning information by time slot on the sleep management application 112.

Figure 28 is a diagram showing sleep management statistics in this embodiment.

The user terminal 110 outputs a sleep assistant on the sleep management application 112 and allows the user to easily wake up at a preset time. The user terminal 110 outputs sleep trends by week and month on the sleep management application 112. The user terminal 110 outputs sleep index, sleep heart rate, sleep time, breathing disorder index, sleep efficiency, and overall sleep time as sleep trends on the sleep management application 112.

The vital radar sensor 1530 of the stone bed 120 generates vital data by sensing heart and breathing. The user terminal 110 receives vital data using the sleep management application 112. The sleep management application 112 determines heart rate, breathing interval, and tossing and turning based on vital data. The sleep management application 112 provides sleep quality by managing sleep based on heart rate, breathing interval, and tossing and turning.

The sleep management application 112 measures apnea based on breathing intervals. The sleep management application 112 determines apnea if breathing does not occur for a preset time (more than 10 seconds) based on the breathing interval. The sleep management application 112 determines the degree of tossing and turning of the user based on motion.

The sleep management application 112 calculates total sleep time, actual sleep time, heart rate, tossing and turning, and tossing and turning index. The sleep management application 112 calculates the total sleep time as actual sleep within the set sleep time range. The sleep management application 112 determines the start (entry) of sleep as the start of sleep if it is within the range of the set sleep time and the user continues to stay in the room without tossing and turning for a preset time (4 minutes). The sleep management application 112 recognizes the end (release) of sleep when absence or tossing and turning continues for a preset time (3 minutes), or when it exceeds the set sleep time range.

The sleep management application 112 calculates the actual sleep time as the sleep time excluding tossing and turning or brief absences (such as going to the bathroom) from the total sleep time. The sleep management application 112 may cause the heart rate to be lower than usual during deep sleep. In REM sleep, etc., the heart rate is calculated in a way that the heart rate increases in the same way as usual. The sleep management application 112 may cause the heart rate to be lower than usual during deep sleep. In REM sleep, etc., the heart rate is calculated by increasing the heart rate as usual. The sleep management application 112 increases the value as there is less tossing and turning. The tossing and turning index is calculated in such a way that the value decreases as the amount of tossing and turning increases.

The user terminal 110 receives vital data from the stone bed 120 using the installed sleep management application 112. The user terminal 110 provides sleep management for the user by analyzing vital data using the installed sleep management application 112.

The user terminal 110 analyzes vital data using the installed sleep management application 112 to determine the user's heart rate, breathing rate, and tossing and turning while sleeping. The user terminal 110 provides sleep management based on heart rate, breathing rate, and tossing and turning using the installed sleep management application 112.

The user terminal 110 determines status information based on heart rate, breathing rate, and tossing and turning using the installed sleep management application 112. The user terminal 110 uses the installed sleep management application 112 to recognize that the user is absent when the status information is 0. The user terminal 110 uses the installed sleep management application 112 to output the user's heart rate and respiratory rate when the status information is 1 to 3. The user terminal 110 uses the installed sleep management application 112 to output that the user is in a moving state when the status information is 4.

The user terminal 110 uses the installed sleep management application 112 to output sleep trends for the user by week and month, and the sleep trends include sleep index, sleep heart rate, sleep time, breathing disorder index, sleep efficiency, and overall sleep trend. Calculate and print sleep time.

When the user terminal 110 determines whether to sleep based on heart rate, breathing rate, and tossing and turning using the installed sleep management application 112, the user terminal 110 calculates the total sleep time by actually sleeping within a preset sleep time range.

The user terminal 110 determines that sleep has begun when it is within the range of a preset sleep time using the installed sleep management application 112 and the user continues to stay in the room without tossing and turning for a preset time (4 minutes).

The user terminal 110 uses the installed sleep management application 112 to recognize the end of sleep when the user is absent for a preset time (3 minutes), continues tossing and turning, or exceeds the preset sleep time range.

The user terminal 110 uses the installed sleep management application 112 to calculate the total sleep time based on sleep start and sleep end, and calculates the actual sleep time by excluding tossing and turning or absences (toilet, etc.) from the total sleep time. Calculate time.

When the user terminal 110 analyzes vital data using the installed sleep management application 112 to determine the user's heart rate at bedtime, a lower heart rate than usual is applied during deep sleep, and the heart rate is lower than usual during REM sleep. The heart rate is calculated in the same way that the heart rate increases.

The above description is merely an illustrative explanation of the technical idea of the present embodiment, and those skilled in the art will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are not intended to limit the technical idea of the present embodiment, but rather to explain it, and the scope of the technical idea of the present embodiment is not limited by these examples. The scope of protection of this embodiment should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of this embodiment.

110: user terminal
112: Sleep management application
120: Stone bed

Claims (8)

A water vein blocking sheet that is laid on the floor inside the wooden frame and blocks the water vein; A copper plate laminated on the water vein blocking sheet and blocking the water vein; A heat insulating and shock absorbing cushioning agent applied in a laminated form on the copper plate to insulate and absorb shock; A special insulating sheet that is installed in a laminated form on the heat insulating and shock absorbing cushion to block electricity or heat; Heating means installed in a laminated form on the special insulating sheet to generate heat; A vital radar sensor that is laminated on or inserted into the heating means and collects vital data from the user present on the natural stone mattress using radar signals; An electromagnetic wave blocking sheet that is installed in a stacked form on the heating means so that only the ultra-long waves are received when the ultra-long waves are radiated from the ultra-long wave coil and the remaining harmful electromagnetic waves are removed; A stone bed including the natural stone mattress installed in a stacked form on the electromagnetic wave blocking sheet;
It includes; a user terminal that receives the vital data from the stone bed using a mounted sleep management application, analyzes the vital data, and provides sleep management for the user;
When the heating means is a film-type planar heating element, the stone bed includes a heating floor installed at the edge and center on the copper plate to secure a space spaced apart by a preset distance,
A space separated by a preset distance is secured between the copper plate and the electromagnetic wave blocking sheet in a space where the heating floor is not installed,
A sleep management system, wherein the heat insulating and shock absorbing cushion, the special insulating sheet, the heating means, and the vital radar sensor are disposed in the spaced space, which is a space where the heating floor is not installed. According to paragraph 1,
The user terminal is,
Characterized by analyzing the vital data using the sleep management application to determine the user's heart rate, respiration rate, and tossing and turning while sleeping, and providing sleep management based on the heart rate, respiration rate, and tossing and turning. Sleep management system. According to paragraph 2,
The user terminal is,
Using the sleep management application, status information is determined based on the heart rate, breathing rate, and tossing and turning, and if the status information is 0, the user is recognized as absent, and if the status information is 1 to 3, the user is recognized as absent. A sleep management system that outputs the heart rate and respiratory rate for and, if the status information is 4, outputs that the user is in a movement state. According to paragraph 2,
The user terminal is,
Using the sleep management application, sleep trends for the user are output by week and month, and sleep index, sleep heart rate, sleep time, breathing disorder index, sleep efficiency, and overall sleep time are calculated and output based on the sleep trend. Features a sleep management system. According to paragraph 2,
The user terminal is,
When determining whether to sleep based on the heart rate, the breathing rate, and the tossing and turning, the total sleep time is calculated as actual sleep within a preset sleep time range, and tossing and turning for a preset time while remaining within the range of the preset sleep time. A sleep management system characterized in that it is determined that sleep has started when the state of presence continues, and that sleep has ended when absence, continued tossing and turning for a preset time, or exceeding the preset sleep time range are recognized. According to clause 5,
The user terminal is,
A sleep management system, characterized in that the total sleep time is calculated based on the sleep start and the sleep end, and the actual sleep time is calculated as the sleep time excluding tossing and turning or absence from the total sleep time. According to paragraph 2,
The user terminal is,
When determining the heart rate at bedtime for the user by analyzing the vital data, a lower heart rate than usual is applied during deep sleep, and the heart rate is calculated in such a way that the heart rate increases at the same level as usual during REM sleep. Features a sleep management system. According to paragraph 1,
The natural stone mattress,
A stone bed characterized in that it further includes a weight detection unit that detects the user's weight when the user lies down, determines whether the user is using the bed, and applies a detection signal to the vital radar sensor connected to the output terminal to turn on the operation. Sleep management system used.