CN114766864A - Partitioned intelligent temperature control mattress - Google Patents

Abstract

The invention discloses a partitioned intelligent temperature control mattress, which comprises a mattress body, wherein the mattress body comprises a control module and a plurality of heating partitioning modules; the heating partition module comprises a partition body, a partition switch unit, a heating unit and a pressure detection piece; the heating unit and the pressure detection piece are arranged on the partition body, the heating unit can generate heat, and the pressure detection piece is used for detecting the pressure on the partition body and generating a pressure detection signal; the control module is used for outputting a driving control signal based on the pressure detection signal and the first target pressure signal; the input end of the separation switch unit is electrically connected with the output end of the control module, the output end of the separation switch unit is electrically connected with the heating unit, and the separation switch unit is used for controlling the working state of the heating unit based on the driving control signal. By adopting the scheme, the problems that the body movement of the user causes that the user does not sleep in the appointed heating area during sleeping, so that the electric energy is wasted and the sleeping quality of the user cannot be improved are solved.

Description

Partitioned intelligent temperature control mattress

Technical Field

The invention relates to the technical field of mattresses, in particular to a partitioned intelligent temperature control mattress.

Background

The mattress is an article between a human body and a bed and used for ensuring that a consumer obtains healthy and comfortable sleep, and is made of various materials. The variety is also various, and the mattress mainly comprises a palm mattress, a modern palm mattress, a latex mattress, a 3D mattress, a spring mattress, an air mattress, a water mattress, a baby mattress and a children mattress. With the improvement of the living standard, people have higher and higher requirements on sleep quality and mattresses. Since heating of different parts of the body also enables a comfortable and relaxing experience, heating mattresses have been developed to meet the above-mentioned needs of users.

Most heating mattresses are now integrated and essentially fixed (fixed temperature, fixed switches), resulting in high post-maintenance costs. Even if the mattress can be heated in a subarea mode, the appointed area can be started to heat according to the selection of the user, however, the situation that the user does not sleep in the appointed heating area due to large body movement of many users during sleeping can occur, the electric energy is consumed due to ineffective heating of the appointed area, and the sleeping quality of the user cannot be improved.

Disclosure of Invention

The invention provides a partitioned intelligent temperature control mattress, which aims to solve the problems that electric energy is wasted and the sleep quality of a user cannot be improved due to the fact that the user does not sleep in a specified heating area due to body movement during sleep.

According to an aspect of the present invention, there is provided a partitioned intelligent temperature control mattress, comprising a mattress body including a control module and a plurality of heat generation partitioning modules;

the heating partition module comprises a partition body, a partition switch unit, a heating unit and a pressure detection piece;

the heating unit and the pressure detection piece are arranged on the partition body, the heating unit can generate heat, and the pressure detection piece is used for detecting the pressure on the partition body and generating a pressure detection signal;

the input end of the control module is electrically connected with the pressure detection piece, and the control module is used for outputting a driving control signal based on the pressure detection signal and a first target pressure signal;

the input end of the separation switch unit is electrically connected with the output end of the control module, the output end of the separation switch unit is electrically connected with the heating unit, and the separation switch unit is used for controlling the working state of the heating unit based on the driving control signal.

In an alternative embodiment of the present invention, the driving control signal includes an on driving signal and an off driving signal; the control module is specifically configured to:

determining whether the pressure detection signal is greater than a first target pressure signal;

if the pressure detection signal is greater than a first target pressure signal, outputting a starting drive signal;

if the pressure detection signal is less than or equal to the first target pressure signal, outputting a closing driving signal;

the partition switch unit is used for controlling the heating unit to be switched on based on the switching-on driving signal and controlling the heating unit to be switched off based on the switching-off driving signal.

In an optional embodiment of the present invention, the partitioned intelligent temperature control mattress further comprises at least one of a regulating module and a communication module;

the adjusting module is used for acquiring user operation information and generating an adjusting signal;

the communication module is used for wirelessly communicating with a terminal to obtain an adjusting signal;

the control end of the control module is electrically connected with the adjusting module and/or the communication module, and the control module is further used for outputting a driving control signal based on the adjusting signal.

In an optional embodiment of the present invention, the adjustment signal includes an induction heating adjustment signal, and the control module is specifically configured to:

determining whether the induction heating adjustment signal is acquired;

if yes, executing the step of determining whether the pressure detection signal is larger than a first target pressure signal.

In an optional embodiment of the present invention, the adjustment signal includes a warm adjusted signal, and the control module is specifically configured to:

determining whether the warm conditioned signal is acquired;

if so, outputting a starting driving signal, and determining whether the pressure detection signal is greater than a second target pressure signal in real time;

if the pressure detection signal is greater than the second target pressure signal, outputting a closing driving signal;

and if the pressure detection signal is less than or equal to the second target pressure signal, outputting a starting driving signal.

In an alternative embodiment of the invention, the adjustment signal comprises a block select signal; the control module is specifically configured to:

outputting the driving control signal to the partition switch unit of the corresponding heat-generating partition module based on the block selection signal.

In an optional embodiment of the present invention, the heat generating partition module further includes a temperature detecting element, and the temperature detecting element is disposed on the partition body and is used for detecting temperature information of the partition body;

the input end of the control module is electrically connected with the temperature detection piece, and the control module is used for determining whether the temperature information exceeds a preset high-temperature threshold value and outputting the closing driving signal when the temperature information exceeds the preset high-temperature threshold value; and the controller is used for determining whether the temperature information is lower than a preset low-temperature threshold value or not and outputting the starting driving signal when the temperature information is lower than the preset low-temperature threshold value.

In an optional embodiment of the present invention, the heat generation region module further comprises at least one of:

the current detection piece is connected with the heating unit in series and used for detecting current information flowing through the heating unit, and the current input end of the control module is electrically connected with the current detection piece and used for determining whether the current information exceeds a preset current range and sending an early warning signal when the current information exceeds the preset current range;

the voltage detection piece is connected with the heating unit in parallel and used for detecting the voltage information of the heating unit, and the voltage input end of the control module is electrically connected with the voltage detection piece and used for determining whether the voltage information exceeds a preset voltage range or not and sending out an early warning signal when the voltage information exceeds the preset voltage range.

In an alternative embodiment of the invention, the heat generating unit comprises an infrared heating tube;

and/or the heating unit comprises a heat conduction pipe and a heating resistor, wherein heat conduction oil is arranged in the heat conduction pipe, and the heating resistor is arranged in the heat conduction pipe.

In an optional embodiment of the invention, the partitioning body comprises a comfort layer, an upper heat insulation layer, a heating layer, a lower heat insulation layer and a supporting layer which are sequentially arranged from top to bottom;

the heating unit is arranged on the heating layer.

According to the technical scheme, the heating area module comprises an area body, an area switch unit, a heating unit and a pressure detection piece, the heating unit and the pressure detection piece are arranged on the area body, the heating unit can emit heat, the pressure detection piece is used for detecting pressure on the area body and generating a pressure detection signal, the input end of the control module is electrically connected with the pressure detection piece, the control module can output a driving control signal based on the pressure detection signal and a first target pressure signal, and the area switch unit is used for controlling the working state of the heating unit based on the driving control signal. The event is when the user is sleeping, separate the module to the district that generates heat that the user contacted, pressure detection signal can be great, control module can output drive control signal this moment, and then separate switch unit can control the unit that generates heat and begin work, the effect of starting the unit that generates heat according to pressure has been realized, thereby only the district that generates heat that the user contacted separates the module and just can generate heat, the district that generates heat that the user did not contact separates the module and does not generate heat, no matter how the user moves and can make the region that contacts generate heat, it causes not to sleep when having solved the user sleep and leads to extravagant electric energy and can't improve the problem of user's sleep quality in appointed heating region. The effects of improving the sleep quality of the user and saving electric energy are achieved.

It should be understood that the statements in this section are not intended to identify key or critical features of the embodiments of the present invention, nor are they intended to limit the scope of the invention. Other features of the present invention will become apparent from the following description.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a partitioned intelligent temperature control mattress according to an embodiment of the present invention;

fig. 2 is a circuit block diagram of a partitioned intelligent temperature control mattress provided by the embodiment of the present invention;

FIG. 3 is a block circuit diagram of another partitioned intelligent temperature controlled mattress according to an embodiment of the present invention;

FIG. 4 is a block diagram of an electrical circuit of another partitioned intelligent temperature controlled mattress according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a partition body according to an embodiment of the present invention.

Wherein: 1. a control module; 2. a heat generation region separation module; 21. a partition body; 211. a comfort layer; 212. an upper heat-insulating layer; 213. a heat generating layer; 214. a lower insulating layer; 215. a support layer; 22. a partition switch unit; 23. a heat generating unit; 24. a pressure detecting member; 25. a temperature detection member; 26. a current detecting member; 27. a voltage detection member; 3. a mattress body; 4. an adjustment module; 5. and a communication module.

Detailed Description

In order to make the technical solutions of the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Example one

Fig. 1 is a structural block diagram of a partitioned intelligent temperature-controlled mattress according to an embodiment of the present invention, and fig. 2 is a circuit block diagram of the partitioned intelligent temperature-controlled mattress according to the embodiment of the present invention, as shown in fig. 1 and fig. 2, the partitioned intelligent temperature-controlled mattress includes a mattress body 3, and the mattress body 3 includes a control module 1 and a plurality of heat generation partitioning modules 2. The arrangement mode of the plurality of heating partition modules 2 may be various according to the difference of the number, for example, when the number of the heating partition modules 2 is 9, the heating partition modules may be arranged according to 9 grids, when the number of the heating partition modules 2 is three, the heating partition modules 2 may be arranged in the width direction of the partitioned intelligent temperature control mattress, and the heating partition modules 2 at different positions may also be named after the arrangement. The control module 1 refers to a module capable of receiving test data reported by each module and intelligently regulating and controlling each module according to a preset program, and in a specific embodiment, the control module 1 may include a microprocessor, such as a single chip microcomputer.

The heat generation partitioning module 2 includes a partitioning body 21 (not shown in fig. 1), a partitioning switch unit 22, a heat generation unit 23, and a pressure detection member 24.

The heat generating unit 23 and the pressure detecting member 24 are disposed on the partition body 21, the heat generating unit 23 can generate heat, and the pressure detecting member 24 is used for detecting the pressure on the partition body 21 and generating a pressure detection signal. The heat generating unit 23 is a heating device capable of converting electric energy into heat energy, and the pressure detecting unit 24 is a member capable of detecting pressure applied to the partitioning main body 21. In one particular embodiment, the pressure sensing member 24 may be a pressure sensor.

The input end of the control module 1 is electrically connected with the pressure detection piece 24, and the control module 1 is used for outputting a driving control signal based on the pressure detection signal and the first target pressure signal. The first target pressure signal is a pressure threshold value above which the pressure detection signal is greater when the person lies on the partitioning body 21. When the body part of the user does not contact the partitioning body 21, no pressure is applied to the partitioning body 21, and the generated pressure detection signal is small, and when the body part of the user contacts the partitioning body 21, the user has weight, so that pressure is generated on the partitioning body 21, and the generated pressure detection signal is large. The first target pressure signal is a pressure threshold value that can distinguish whether the user touches the partition body 21.

The input end of the partition switch unit 22 is electrically connected with the output end of the control module 1, the output end of the partition switch unit 22 is electrically connected with the heating unit 23, and the partition switch unit 22 is used for controlling the working state of the heating unit 23 based on the driving control signal. The operating state of the heating unit 23 refers to a heating state and a heating stop state, the partition switch unit 22 refers to a unit capable of controlling whether the heating unit 23 is powered, when the heating unit 23 is powered, the heating unit 23 starts to operate and is in the heating state, but when the heating unit 23 is powered off, the heating unit 23 stops operating and is in the heating stop state.

In the above solution, by providing the control module 1 and the plurality of heat generating region separating modules 2, the heat generating region separating modules 2 include a region separating body 21, a region separating switch unit 22, a heat generating unit 23 and a pressure detecting element 24, the heat generating unit 23 and the pressure detecting element 24 are disposed on the region separating body 21, the heat generating unit 23 can generate heat, the pressure detecting element 24 is used for detecting the pressure on the region separating body 21 and generating a pressure detecting signal, the input end of the control module 1 is electrically connected to the pressure detecting element 24, the control module 1 can output a driving control signal based on the pressure detecting signal and a first target pressure signal, and the region separating switch unit 22 is used for controlling the operating state of the heat generating unit 23 based on the driving control signal. Therefore, when a user sleeps, the heating partition module 2 contacted by the user is subjected to a larger pressure detection signal, the control module 1 outputs a driving control signal at the moment, the partition switch unit 22 controls the heating unit 23 to start working, the effect of starting the heating unit 23 according to the pressure is realized, only the heating partition module 2 contacted by the user can heat, the heating partition module 2 not contacted by the user does not heat, the contacted area can be heated no matter how the user moves, and the problems that the user does not sleep in a specified heating area to waste electric energy and the sleep quality of the user cannot be improved due to the fact that the user moves when sleeping are solved. The effects of improving the sleep quality of the user and saving electric energy are achieved.

In an alternative embodiment of the present invention, the driving control signal includes an on driving signal and an off driving signal; the control module 1 is specifically configured to:

it is determined whether the pressure detection signal is greater than a first target pressure signal.

And if the pressure detection signal is greater than the first target pressure signal, outputting an opening driving signal.

And if the pressure detection signal is less than or equal to the first target pressure signal, outputting a closing driving signal.

The partition switching unit 22 is used to control the heat generating unit 23 to be turned on based on the on driving signal and to control the heat generating unit 23 to be turned off based on the off driving signal.

When the pressure detection signal is greater than the first target pressure signal, it indicates that the user contacts the heating partition module 2, and at this time, the start driving signal is output, so that the partition switch unit 22 controls the heating unit 23 to be started, and the effect of starting heating of the heating partition module 2 contacted by the user is achieved, no matter how the user moves, the contacted area is heated, and the problem that the sleep quality of the user cannot be improved due to the fact that the user does not sleep in the designated heating area due to the movement of the user during the sleep is solved. When the pressure detection signal is smaller than the second target pressure signal, it indicates that the user contacts the heating partition module 2, and at this time, the closing driving signal is output, so that the partition switch unit 22 controls the heating unit 23 to close, an effect of stopping heating of an area which is not contacted by the user is achieved, the problem that the heating area is ineffective and generates heat to waste electric energy due to the fact that the user does not sleep in the designated heating area due to body movement during sleeping is solved, and electric energy is saved.

In an alternative embodiment of the present invention, as shown in fig. 3, the partitioned intelligent temperature control mattress further includes at least one of a regulating module 4 and a communication module 5.

The adjusting module 4 is used for acquiring the user operation information and generating an adjusting signal.

The communication module 5 is used for wireless communication with the terminal to obtain the adjusting signal.

The control end of the control module 1 is electrically connected with the adjusting module 4 and/or the communication module 5, and the control module 1 is further configured to output a driving control signal based on the adjusting signal.

The communication module 5 is a module capable of performing wireless communication with a terminal, and in a specific embodiment, the communication module 5 includes at least one of a bluetooth module and a WIFI module. The terminal is an intelligent device capable of being wirelessly controlled by a user, such as a mobile phone, a computer, an intelligent watch and the like. The adjusting module 4 is a module that can be directly operated and controlled by a user, for example, the adjusting module 4 includes a selection key, the user can input an adjusting signal to the control module 1 by pressing the selection key, and the number of the selection keys may be multiple, so that the user can input different types of adjusting signals to the control module 1 when pressing different selection keys. Or the number of the selection keys is one, and when different keys are pressed, different types of adjustment signals can be input into the control module 1, and in a specific embodiment, the adjustment module 4 can comprise a remote controller and the like. The specific structures of the communication module 5 and the adjustment module 4 are not specifically limited, but are merely illustrative.

On the basis of the above embodiment, the adjustment signal includes an induction heating adjustment signal, and the control module 1 is specifically configured to:

it is determined whether an induction heating adjustment signal is acquired.

If yes, executing the step of determining whether the pressure detection signal is larger than the first target pressure signal.

For example, when there are many people sleeping on the mattress, the function of starting heating of all the heating partition modules 2 can be directly started. Therefore, by determining whether the induction heating adjustment signal is acquired or not, and executing the step of determining whether the pressure detection signal is greater than the first target pressure signal or not after the induction heating adjustment signal is acquired, the user's needs can be better satisfied. Further, when the induction heating adjustment signal is not acquired, it may be continuously determined whether the induction heating adjustment signal is acquired.

In an alternative embodiment of the present invention, the adjustment signal includes a warm adjusted signal, and the control module 1 is specifically configured to:

it is determined whether a warm conditioned signal is acquired.

If yes, outputting a starting driving signal, and determining whether the pressure detection signal is larger than a second target pressure signal in real time.

And if the pressure detection signal is greater than the second target pressure signal, outputting a closing driving signal.

And if the pressure detection signal is less than or equal to the second target pressure signal, outputting a starting driving signal.

Wherein the second target pressure signal refers to a pressure threshold value that can distinguish whether the user touches the partitioning body 21. The second target pressure signal may be the same magnitude as the first target pressure signal, or may have a certain float range. When the pressure detection signal is greater than the second target pressure signal, it indicates that the user touches the heat generation region module 2, and at this time, the off driving signal is output, and the heat generation unit 23 stops generating heat. When the pressure detection signal is less than or equal to the second target pressure signal, which indicates that the user does not contact the heat generation region module 2 at this time, the heat generation unit 23 starts to generate heat. Some users feel discomfort because they do not like the body parts to directly contact the heat source, but they are difficult to generate heat due to the cold weather, and thus need to get warm. When the warm quilt adjustment signal is acquired, the starting driving signal is output firstly, the heating unit 23 can start heating at the moment, and then the quilt can be in a warm state at the moment, so that a user can output the warm quilt adjustment signal through the terminal or directly control the adjusting module 4 to output the warm quilt adjustment signal in advance, the quilt can be in the warm state at the moment, when the user gets into bed, the pressure of a region contacted by the user is large, the heating separation module 2 in the region can stop heating, and the condition that the user directly approaches to a heating source to cause discomfort is prevented. Therefore, the scheme can prevent the user from being directly close to the heating source to cause the uncomfortable condition to happen, enables the user who is afraid of severe cold to be still in a warm state, improves the user experience, and plays a role in assisting sleep.

In an alternative embodiment of the invention, the adjustment signal comprises a block select signal; the control module 1 is specifically configured to:

the driving control signal is output to the partition switching unit 22 of the corresponding heat generation partition module 2 based on the block selection signal.

The block selection signal is an electrical signal of the heat generation separating module 2 reflecting a specific position selected by a user. By outputting the driving control signal to the partition switch unit 22 of the corresponding heat partition module 2 based on the block selection signal, the heat partition module 2 of the user selection area can be controlled to start to heat based on the selection of the user, which is convenient for meeting different requirements of the user and has strong adaptability.

In an alternative embodiment of the present invention, as shown in fig. 4, taking the control module 1 controlling a single heat-generating separating module 2 as an example, the heat-generating separating module 2 further includes a temperature detecting element 25, and the temperature detecting element 25 is disposed on the separating body 21 and is used for detecting temperature information of the separating body 21; the input end of the control module 1 is electrically connected with the temperature detection piece 25, and the control module 1 is used for determining whether the temperature information exceeds a preset high-temperature threshold value and outputting a closing driving signal when the temperature information exceeds the preset high-temperature threshold value; and the controller is used for determining whether the temperature information is lower than a preset low-temperature threshold value or not and outputting a starting driving signal when the temperature information is lower than the preset low-temperature threshold value.

The temperature detecting member 25 is a member capable of detecting temperature, and in a specific embodiment, the temperature detecting member 25 may be a temperature sensor. The preset high temperature threshold is the highest temperature of the user in the comfortable zone, the preset low temperature threshold is the lowest temperature of the user in the comfortable zone, and the preset high temperature threshold and the preset low temperature threshold can be set by a manufacturer or can be set by the user through self input, for example, the user inputs the preset high temperature threshold and the preset low temperature threshold through an operation terminal or the adjusting module 4. Through output when temperature information exceedes preset high temperature threshold and closes drive signal, the unit 23 that generates heat this moment can stop generating heat, outputs when temperature information is less than preset low temperature threshold and opens drive signal to the unit 23 that generates heat can open and generate heat, thereby can separate the temperature control of module 2 at the temperature range of predetermineeing with generating heat, has played the effect of control by temperature change.

In an optional embodiment of the present invention, the control module 1 may further obtain the heating time and the heating time period through the adjusting module 4 and/or the communication module 5, and control the heat generation separation module 2 to start heating from the heating time and to heat the heating time period according to the heating time and the heating time period.

In an alternative embodiment of the invention, the heat generation separation module 2 further comprises at least one of:

the current detection part 26 is connected in series with the heating unit 23 and used for detecting current information flowing through the heating unit 23, and a current input end of the control module 1 is electrically connected with the current detection part 26 and used for determining whether the current information exceeds a preset current range or not and sending out an early warning signal when the current information exceeds the preset current range. The current detector 26 is a component capable of detecting a current value, and in a specific embodiment, the current detector 26 includes an ammeter. The heating unit 23 usually has a range in which the current is in when the heating unit is normal, that is, a preset current range, and when the current exceeds the preset current range, it indicates that the heating unit 23 may work in an overload state or a circuit has a fault, and at this time, an early warning signal is sent out, so that a user can conveniently and timely process the fault, and the user is prevented from being injured. The warning signal may be sent in various ways, for example, the communication module 5 may send the warning information to the terminal of the user in a short message manner, or the heating partition module 2 has a display screen, and the warning information is displayed on the display screen, or the heating partition module 2 may include a buzzer, and the buzzer buzzes to make the user know the warning information.

The voltage detection part 27 is connected with the heating unit 23 in parallel and used for detecting the voltage information of the heating unit 23, and the voltage input end of the control module 1 is electrically connected with the voltage detection part 27 and used for determining whether the voltage information exceeds a preset voltage range or not and sending out an early warning signal when the voltage information exceeds the preset voltage range. The voltage detecting element 27 is a component capable of detecting a voltage value, and in a specific embodiment, the voltage detecting element 27 includes a voltmeter. The preset voltage range refers to a range within which the heating unit 23 does not exceed during normal operation, and when the voltage information exceeds the preset voltage range, it is indicated that the heating unit 23 may work in an overload state or a circuit fails, and at this time, an early warning signal is sent out, so that a user can timely handle the failure, and the user is prevented from being injured.

In an optional embodiment of the present invention, the control module 1 may further send the current information, the voltage information, and the temperature information to the terminal through the communication module 5, so as to be convenient for the user to view. Simultaneously, including display device when this subregion intelligence control by temperature change mattress, control module 1 also can be with current information, voltage information and temperature information transmission to display device, and the user of being convenient for looks over through display device, and display device can include LED display screen, LCD display screen etc..

The power that this subregion intelligence control by temperature change mattress used can be one or more in external power supply and the internal power supply, and external power supply can be commercial power etc. and internal power supply includes battery etc. still can be equipped with the master switch who establishes ties with the power simultaneously, is convenient for control opening and close of whole subregion intelligence control by temperature change mattress.

In an alternative embodiment of the present invention, the heat generating unit 23 comprises an infrared heating pipe; wherein, the infrared heating pipe is a tubular heater utilizing the infrared principle. Compared with other heat conducting devices, the infrared heating pipe is more efficient, and has the characteristics of high conversion rate, safety, controllability and few parts.

In an alternative embodiment of the present invention, the heat generating unit 23 includes a heat conducting pipe and a heat generating resistor, the heat conducting pipe is provided with heat conducting oil therein, and the heat generating resistor is provided in the heat conducting pipe. Wherein, the heating resistor generates heat when being electrified, thereby being capable of converting the electric quantity into heat. The heat conducting oil is used as a heat transfer medium, so that high temperature control precision can be ensured, and the heat conducting oil has the characteristics of high heat efficiency and wide temperature range.

In an alternative embodiment of the present invention, as shown in fig. 5, the partitioning body 21 includes a comfort layer 211, an upper insulating layer 212, a heat generating layer 213, a lower insulating layer 214, and a supporting layer 215, which are sequentially disposed from top to bottom; the heat generating unit 23 (not shown in fig. 5) is disposed on the heat generating layer 213.

Wherein, comfortable layer 211 provides better experience for the user, should guarantee comfortable soft, and main material can include any one in latex, sponge or the gel material. Go up heat preservation 212 and heat preservation 214 down can be the same material, play heat retaining effect, can use the cotton material of high temperature resistant 3D, guarantee that the gas permeability is good simultaneously for the support nature. The heating layer 213 mainly heats through the heating unit 23 disposed thereon, and the heating layer 213 may include a flexible tin foil material to control the direction of heat energy propagation; the support layer 215 mainly serves as a support, and the support layer 215 may include a separate cartridge spring and coconut hair.

It should be understood that various forms of the flows shown above may be used, with steps reordered, added, or deleted. For example, the steps described in the present invention may be executed in parallel, sequentially, or in different orders, and are not limited herein as long as the desired result of the technical solution of the present invention can be achieved.

The above-described embodiments should not be construed as limiting the scope of the invention. It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and substitutions may be made in accordance with design requirements and other factors. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The partitioned intelligent temperature control mattress is characterized by comprising a mattress body (3), wherein the mattress body (3) comprises a control module (1) and a plurality of heating partition modules (2);

the heating separation module (2) comprises a separation body (21), a separation switch unit (22), a heating unit (23) and a pressure detection piece (24);

the heating unit (23) and the pressure detecting piece (24) are arranged on the partition body (21), the heating unit (23) can generate heat, and the pressure detecting piece (24) is used for detecting the pressure on the partition body (21) and generating a pressure detecting signal;

the input end of the control module (1) is electrically connected with the pressure detection piece (24), and the control module (1) is used for outputting a driving control signal based on the pressure detection signal and a first target pressure signal;

the input end of the separation switch unit (22) is electrically connected with the output end of the control module (1), the output end of the separation switch unit (22) is electrically connected with the heating unit (23), and the separation switch unit (22) is used for controlling the working state of the heating unit (23) based on the driving control signal.

2. The partitioned intelligent temperature controlled mattress according to claim 1, wherein said drive control signals include an on drive signal and an off drive signal; the control module (1) is specifically configured to:

determining whether the pressure detection signal is greater than a first target pressure signal;

if the pressure detection signal is greater than the first target pressure signal, outputting a starting driving signal;

if the pressure detection signal is less than or equal to a first target pressure signal, outputting a closing driving signal;

the partition switch unit (22) is used for controlling the heating unit (23) to be turned on based on the turn-on driving signal and controlling the heating unit (23) to be turned off based on the turn-off driving signal.

3. The zoned intelligent temperature controlled mattress according to claim 2, further comprising at least one of a conditioning module (4) and a communication module (5);

the adjusting module (4) is used for acquiring user operation information and generating an adjusting signal;

the communication module (5) is used for wirelessly communicating with a terminal to obtain an adjusting signal;

the control end of the control module (1) is electrically connected with the adjusting module (4) and/or the communication module (5), and the control module (1) is also used for outputting a driving control signal based on the adjusting signal.

4. The partitioned intelligent temperature controlled mattress according to claim 3, wherein the conditioning signals comprise induction heating conditioning signals, the control module (1) being specifically configured to:

determining whether the induction heating adjustment signal is acquired;

if yes, executing the step of determining whether the pressure detection signal is larger than a first target pressure signal.

5. Partitioned intelligent temperature controlled mattress according to claim 3, wherein said adjustment signals comprise warm adjusted signals, said control module (1) being particularly adapted to:

determining whether the warm conditioned signal is acquired;

if so, outputting a starting driving signal, and determining whether the pressure detection signal is greater than a second target pressure signal in real time;

if the pressure detection signal is greater than the second target pressure signal, outputting a closing driving signal;

and if the pressure detection signal is less than or equal to the second target pressure signal, outputting a starting driving signal.

6. The partitioned intelligent temperature controlled mattress of claim 3, wherein the conditioning signal comprises a block select signal; the control module (1) is specifically configured to:

outputting the driving control signal to the partition switching unit (22) of the corresponding heat-generating partition module (2) based on the block selection signal.

7. The partitioned intelligent temperature control mattress according to any one of claims 2 to 6, characterized in that the heating partition module (2) further comprises a temperature detecting member (25), the temperature detecting member (25) is arranged on the partition body (21) for detecting temperature information of the partition body (21);

the input end of the control module (1) is electrically connected with the temperature detection piece (25), and the control module (1) is used for determining whether the temperature information exceeds a preset high-temperature threshold value and outputting the closing driving signal when the temperature information exceeds the preset high-temperature threshold value; and the control circuit is used for determining whether the temperature information is lower than a preset low-temperature threshold value or not and outputting the starting driving signal when the temperature information is lower than the preset low-temperature threshold value.

8. The partitioned intelligent temperature controlled mattress according to any one of claims 2 to 6, characterized in that the heat generation partition module (2) further comprises at least one of:

the current detection piece (26) is connected with the heating unit (23) in series and used for detecting current information flowing through the heating unit (23), and a current input end of the control module (1) is electrically connected with the current detection piece (26) and used for determining whether the current information exceeds a preset current range and sending an early warning signal when the current information exceeds the preset current range;

the voltage detection piece (27), voltage detection piece (27) with generate heat unit (23) are parallelly connected, are used for detecting the voltage information of generating heat unit (23), the voltage input of control module (1) with voltage detection piece (27) electricity is connected, is used for confirming whether voltage information exceedes predetermines the voltage range, and is in voltage information exceedes send early warning signal when predetermineeing the voltage range.

9. The partitioned intelligent temperature-controlled mattress according to any one of claims 1 to 6, characterized in that the heating unit (23) comprises an infrared heating pipe;

and/or the heating unit (23) comprises a heat conduction pipe and a heating resistor, wherein heat conduction oil is arranged in the heat conduction pipe, and the heating resistor is arranged in the heat conduction pipe.

10. The partitioned intelligent temperature control mattress according to any one of claims 1 to 6, wherein the partitioning body (21) comprises a comfort layer (211), an upper heat insulation layer (212), a heating layer (213), a lower heat insulation layer (214) and a support layer (215) which are arranged from top to bottom in sequence;

the heat generating unit (23) is disposed on the heat generating layer (213).

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