CN108272275B - Energy-saving mattress with temperature control function - Google Patents

Abstract

The invention relates to an energy-saving mattress with a temperature control function, which comprises a hard bottom plate, a spring bed net, fillers, fabric and a control module. The spring bed net comprises spiral springs which are uniformly arranged in a parallel matrix to form a spring matrix, air bags are arranged only in the odd springs on the odd spring rows of the spring matrix, and air bags are arranged only in the even springs on the even spring rows of the spring matrix; the bottoms of all the air bags on each transverse row are connected through branch pipelines, main pipelines connected with the branch pipelines in each transverse row are arranged on any side of each branch pipeline, and exhaust valves are respectively arranged on the other sides of the branch pipelines in each transverse row; electromagnetic valves are arranged on the transverse branch pipelines close to the intersection points, and inflators are arranged at the tail ends of the main pipelines. The mattress can realize the adjustment of the elasticity of each part of the mattress according to the requirement, saves electric energy through the crossed distribution of the air bags, and realizes the control and adjustment of the temperature of the mattress according to the requirement aiming at different parts of the body.

Description

Energy-saving mattress with temperature control function

Technical Field

The invention belongs to the field of mattresses, and particularly relates to an energy-saving mattress with a temperature control function.

Background

Due to the improvement of living standards, people are more and more concerned about the safety, health and comfort of household products. The mattress is an article which can ensure the health and comfort of the sleep of consumers, the material is various, the variety is very different, and the spring mattress is one of the products which are popular among people.

With the advancement of science and technology, the selection of the mattress is more and more diversified. The development of the mattress is that materials of various aspects of the mattress are continuously improved, and meanwhile, in order to improve the sleeping comfort of a human body, the design of the zoning of the mattress is gradually developed, and the initial zoning mattress is gradually developed into a five-zoning mattress, a seven-zoning mattress, a nine-zoning mattress and the like.

However, the subareas of the existing subarea mattress are relatively fixed, and if the height of a person (such as a minor) or the head position of the person (such as the position of a pillow) changes, the subareas of the mattress cannot be adjusted correspondingly, so that the uncomfortable sleep feeling is brought. In addition, the prior elastic mattress can not realize the zonal adjustment of the temperature of the mattress.

Disclosure of Invention

In order to solve the technical problems in the prior art, the invention provides an energy-saving mattress with a temperature control function, and the specific technical scheme is as follows.

An energy-saving mattress with a temperature control function comprises a hard bottom plate, a spring bed net, fillers and fabrics which are sequentially arranged from bottom to top; the mattress also comprises a control module;

the spring bed net comprises spiral springs which are arranged in parallel and transversely, and an air bag is arranged in each spiral spring;

the spring bed net comprises spiral springs which are uniformly arranged in a parallel matrix to form a spring matrix, air bags are arranged in odd springs on odd spring rows of the spring matrix, and air bags are arranged in even springs on even spring rows of the spring matrix;

the bottoms of all the air bags on each transverse row are connected through branch pipelines, main pipelines connected with the branch pipelines in each transverse row are arranged on any side of each branch pipeline, and exhaust valves are respectively arranged on the other sides of the branch pipelines in each transverse row;

the main pipeline and each transverse branch pipeline have intersection points, electromagnetic valves are arranged on the branch pipelines close to the intersection points in each transverse row, and an inflator is arranged at the tail end of the main pipeline;

and a pressure sensor array is arranged between the filler and the fabric and used for sensing the pressure of the contact part of the sleeper and the mattress so as to judge the current sleeping position of the sleeper.

Preferably, each row of branch pipelines is respectively provided with an electric heater for heating air in the branch pipelines, and the electric heater is arranged on the branch pipeline between the electromagnetic valve and the exhaust valve.

Preferably, the electric heater is provided with a temperature sensor, and the temperature sensor is used for detecting the air temperature in the branch pipeline.

Preferably, an air flow sensor is arranged on the exhaust valve.

Preferably, the control module comprises a touch screen, a memory and a control unit.

Preferably, an air pressure sensor is arranged in each transverse branch pipeline, and the air pressure sensor can monitor the air pressure value in each transverse branch pipeline and store the measured air pressure value in the memory, so that the memory of the air pressure mode is realized.

Compared with the prior art, the method has the following advantages:

(1) the partitioning of the elasticity of the mattress is realized through the air bag in the spring, and the adjustment of the elasticity of each part of the mattress according to the requirement is realized.

(2) The energy conservation of the mattress is realized by the crossed distribution of the air bags on the adjacent air bag rows.

(3) The zone heating according to the needs of the sleeper is realized by an electric heater.

(4) The partition refrigeration according to the needs of the sleeper is realized by a micro air refrigerator.

Drawings

FIG. 1 is a schematic view of a mattress;

FIG. 2 is a schematic view of the spring and bladder arrangement relative to each other;

fig. 3 is a schematic view of the mutual structure of the air bag and the main and branch pipes.

Wherein, 1-a bottom plate; 2-spring bed net; 3-a filler; 4-fabric; 5-a control module; 21-a spring; 22-air bag; 23-branch pipes; 24-a main pipeline; 25-an exhaust valve; 26-a solenoid valve; 27-an electric heater; 28-micro air refrigerator; 29-inflator

Detailed Description

Example one

An energy-saving mattress with a temperature control function comprises a hard bottom plate 1, a spring bed net 2, fillers 3, fabric 4 and a control module 5. Wherein, the hard bottom plate 1, the spring bed net 2 and the filler 3 are arranged from bottom to top in sequence, and the fabric 4 is coated on the outer surface.

The spring bed net 2 comprises spiral springs 21, the spiral springs 21 are uniformly arranged in a parallel matrix to form a spring matrix, air bags 22 are only arranged in odd springs on odd spring rows of the spring matrix, and the air bags 22 are only arranged in even springs on even spring rows of the spring matrix. For example, the air bags are arranged in the 1 st, 3 rd, 5 … 2n +1 st row springs and the air bags are arranged in the 2 nd, 4 th, 6 … 2n row springs only in the 1 st, 3 rd, 5 … 2n +1 st row springs and the air bags are arranged in the 2 nd, 4 th, 6 … 2n row springs in the spring matrix.

Preferably, the balloon 22 is helical or elliptical.

The bottoms of all the air bags 22 on each transverse row are connected through branch pipelines 23 to form branch pipelines which are transversely distributed in parallel, a main pipeline 24 connected with each transverse branch pipeline 23 is arranged at one end of each branch pipeline 23, each transverse row is provided with an exhaust valve 25 at the other end of each branch pipeline 23, and an air flow sensor is arranged on each exhaust valve 25.

The main pipe 24 and each transverse branch pipe 23 have intersection points, electromagnetic valves 26 are arranged on the branch pipes 23 close to the intersection points, the electromagnetic valves 26 are kept in a normally open state on the premise that no requirement is made on the mattress elastic subareas by sleepers, and an inflator 29 is arranged at the tail end of the main pipe 24.

The control module 5 comprises a touch screen, a memory and a control unit.

Preferably, the control module 5 further comprises a power module, and one end of the power module is connected with a power plug, so that the control module has a control function and a power supply function at the same time.

And a pressure sensor array is arranged between the filler 3 and the fabric 4 and is used for sensing the pressure of the contact part of the sleeper and the mattress, further judging the current sleeping position of the sleeper, further obtaining the transverse line number of the air bag 22 pressed by the sleeper in the current sleeping posture, and displaying the outline of the sleeper and the transverse line number of the air bag 22 corresponding to the outline on the touch screen.

The sleeper adjusts the air pressure of each transverse air bag 22 through the electromagnetic valve 26 and the exhaust valve 25 according to the corresponding relation between the transverse serial number of the air bag 22 and the outline of the sleeper displayed on the touch screen, and further, the sleeper can freely adjust the air pressure of the air bag 22 of each part according to the actual supporting requirement of each part of the body. For example, if it is necessary to increase the air pressure of the third airbag 22, the remaining solenoid valves 26 of the respective transverse rows are closed, the solenoid valve 26 of the third transverse row is opened, the third airbag 22 is restarted by the inflator 29, and so on, so that the air pressures of the plurality of transverse airbags 22 can be simultaneously increased; if the air pressure of the third transverse line needs to be reduced, the electromagnetic valve 26 of the third transverse line opens the exhaust valve 25 at the other side of the third transverse branch pipe 23 to exhaust and reduce the pressure of the air bag 22 of the third transverse line.

Be provided with the pipeline recess on the stereoplasm bottom plate 1, branch pipeline 23, trunk line 24 all set up in the pipeline recess.

Preferably, an air pressure sensor is disposed in each horizontal branch duct 23, and the air pressure sensor can monitor the air pressure value in each horizontal line and store the measured air pressure value in the memory, so as to realize the memory of the air pressure mode.

Example two

The sleeper needs the mattress to be heated to warm the sleeper during sleep, for example, in a cold winter season. Therefore, on the basis of the first embodiment, the mattress capable of automatically heating is further obtained.

An electric heater 27 is respectively arranged on each row of branch pipelines 23 and used for heating air in the branch pipelines 23, and the electric heater 27 is arranged on the branch pipelines 23 between the electromagnetic valve 26 and the exhaust valve 25.

Further, a temperature sensor is further disposed on the electric heater 27, and the temperature sensor is configured to detect an air temperature in the branch duct 23.

The electric heater 27 and the temperature sensor are respectively connected with the control module 5.

The use method of the mattress heating specifically comprises the following steps:

the sleeper adjusts the air pressure of each row of the air bags 22 in the sleeping process; judging the current sleeping position of the sleeper and the number of the transverse rows of the air bags 22 pressed by the current sleeping posture of the sleeper through the pressure sensor array; the sleeper respectively adjusts the temperature of each horizontal row through the electric heater 27 and the temperature sensor according to the temperature requirements of the sleeper on different parts of the body, and then the sleeping temperature of the sleeper is controlled in a partitioning mode.

If the sleeper feels that the preset temperature of a certain air bladder 22 is too high, the temperature of the air bladder 22 may be lowered through the discharge valve 25, the solenoid valve 26, and the inflator 29. For example, the sleeper sets the temperature of the third row to 43 degrees celsius, but after the temperature adjustment, the sleeper considers that 43 degrees celsius is too high and needs to be reduced to 40 degrees celsius, and at this time, the sleeper sets the temperature to 40 degrees celsius through the touch screen, and the control module 5 controls the exhaust valve 25, the solenoid valve 26 and the inflator 29 to be simultaneously opened, and extrudes the original hot air to reduce the temperature of the row by blowing new air into the row branch duct 23.

EXAMPLE III

The sleeper not only needs to heat but also needs to refrigerate in the sleeping process. Therefore, on the basis of the first embodiment or the second embodiment, the mattress capable of automatically cooling is further obtained.

The mattress also comprises a micro air cooler 28, the micro air cooler 28 is arranged at the tail end of the main pipeline 24, and the micro air cooler 28 and the inflator 29 are connected with the main pipeline 24 through a tee joint.

The branches of the tee joint connected with the micro air cooler 28 and the inflator 29 are respectively provided with an electromagnetic valve, so that the micro air cooler 28 and the inflator 29 are respectively connected with the main pipeline 24 through the electromagnetic valves.

The refrigeration method of the mattress specifically comprises the following steps:

before the sleeper sleeps, the number of the transverse rows where the air bags 22 pressed by the sleeper in the current sleeping position and the current sleeping posture are located is obtained through the pressure sensor array; according to the sleeping position and the number of the air bag 22, the sleeper presets the refrigeration temperature values of all rows; the control module 5 arranges the temperature values of all rows preset by the sleeper from high to low; the control module 5 closes the solenoid valve 26 on the branch of the three-way upper inflator 29 and opens the solenoid valve 26 on the branch of the micro air cooler 28; the control module 5 controls the micro air cooler 28 to sequentially convey the cold air to each row according to the sequence of temperature values from high to low, and in the process of conveying the cold air, a sleeper determines the air pressure in each transverse branch pipeline 23 according to the memory of an air pressure mode or the self perception so as to determine the stop of the conveying of the cold air.

If the sleeper senses that the temperature in the transverse air bag 22 is too high in the refrigerating process and needs to continue refrigerating, the temperature of the diversion air bag 22 can be continuously reduced through the cooperation of the exhaust valve 25, the electromagnetic valve 26 and the micro air refrigerator 28, and the principle is the same as that of the second embodiment; if the sleeper senses that the temperature in the transverse air bag 22 is too low and needs to be increased, the control module 5 can control the electric heater 27 to perform appropriate heating, so that the transverse temperature is increased.

Preferably, in order to avoid noise pollution of the micro air cooler 28, a sound insulation device is provided outside the micro air cooler 28.

Preferably, in order to prevent the cold air from flowing in the main pipe 24 to exchange heat with the external air, an insulation device is wrapped outside the main pipe 24.

Example four

The outside air contains a large amount of water vapor, and the inflator 29 or the micro air cooler 28 directly fills the air into the mattress, and the water vapor can be condensed on the inner wall of the pipeline to form water drops, which can affect the service life of the mattress and the cooling/heating effect of the mattress in time.

Thus, in addition to the above embodiments one to three, an air dehumidifying unit having a desiccant including, but not limited to, activated carbon, silica gel or calcium chloride is provided on the main conduit 24 adjacent to the tee/inflator 29.

EXAMPLE five

When a sleeper sleeps, the quilt is easy to kick when the sleeper turns over or is tired excessively, and the quilt is easy to catch a cold if the quilt is not covered in time after the quilt is kicked.

The upper surface of the filler 3 is provided with 24 body temperature sensors, and the 24 body temperature sensors are uniformly distributed along the longitudinal center line of the mattress in four rows.

The upper surface of the filler 3 is provided with a sensor mounting hole, the periphery of the body temperature sensor is mounted in the sensor mounting hole through a heat insulation silica gel plug, the tail of the body temperature sensor is mounted in the sensor mounting hole, the temperature sensing head of the body temperature sensor is exposed out of the outer side of the fabric 4 to sense the body temperature of a sleeper, and an electric wire led out of the tail of the body temperature sensor penetrates through the heat insulation silica gel plug to be connected to the control module 5. The upper surface of the filler 3 is provided with a groove, and the groove is used for placing the electric wire led out from the tail part of the body temperature sensor.

An ambient temperature sensor is arranged on the side face of the spring bed net 2 and connected with the control module 5 for collecting the current ambient temperature.

In the sleeping process of the sleeper, judging the current sleeping position of the sleeper through the pressure sensor array; according to the sleeping position, starting the body temperature sensor closest to the body temperature sensor along the central axis of the sleeping position in each row of the body temperature sensors to respectively obtain the temperature values of the body temperature sensors; comparing the temperature values with the environment temperature values measured by the environment temperature sensors respectively, and if the temperature difference between the temperature values exceeds a certain threshold range, indicating that a sleeper kicks a quilt and the area where the body temperature sensor corresponding to the temperature value is located is exposed in the air; at this time, the control module can control the transverse movement of the area where the body temperature sensor is located to heat so as to prevent the sleeper from catching a cold.

Preferably, the control module further comprises a timer, and the timer is used for starting the pressure sensor array, the body temperature sensor and the ambient temperature sensor at intervals to perform measurement so as to save energy.

The description and applications of the invention herein are illustrative and are not intended to limit the scope of the invention to the embodiments described above. Variations and modifications of the embodiments disclosed herein are possible, and alternative and equivalent various components of the embodiments will be apparent to those skilled in the art. It will be clear to those skilled in the art that the present invention may be embodied in other forms, structures, arrangements, proportions, and with other components, materials, and parts, without departing from the spirit or essential characteristics thereof. Other variations and modifications of the embodiments disclosed herein may be made without departing from the scope and spirit of the invention.

Claims (2)

1. The use method of the energy-saving mattress comprises a hard bottom plate, a spring bed net, fillers, fabric and a control module; wherein the content of the first and second substances,

the hard bottom plate, the spring bed net and the filler are sequentially arranged from bottom to top, and the fabric is coated on the outer surface;

the spring bed net comprises spiral springs which are uniformly arranged in a parallel matrix to form a spring matrix, air bags are arranged only in the odd springs on the odd spring rows of the spring matrix, and air bags are arranged only in the even springs on the even spring rows of the spring matrix;

the bottoms of all the air bags on each transverse row are connected through branch pipelines to form branch pipelines which are transversely distributed in parallel, a main pipeline connected with each transverse branch pipeline is arranged at one end of each branch pipeline, exhaust valves are respectively arranged at the other ends of the branch pipelines on each transverse row, and an air flow sensor is arranged on each exhaust valve;

the main pipeline and each transverse branch pipeline have intersection points, electromagnetic valves are arranged on the branch pipelines close to the intersection points, the electromagnetic valves are kept in a normally open state on the premise that no requirement is made on the mattress elastic subarea by a sleeper, and an inflator is arranged at the tail end of the main pipeline;

a pressure sensor array is arranged between the filler and the fabric and used for sensing the pressure of the contact part of the sleeper and the mattress, further judging the current sleeping position of the sleeper, further obtaining the transverse number of the air bag pressed by the sleeper in the current sleeping posture, and displaying the outline of the sleeper and the transverse number of the air bag corresponding to the outline on the control module;

each row of branch pipelines are respectively provided with an electric heater for heating air in the branch pipelines, and the electric heaters are arranged on the branch pipelines between the electromagnetic valves and the exhaust valves;

the electric heater is also provided with a temperature sensor, and the temperature sensor is used for detecting the air temperature in the branch pipeline;

the mattress also comprises a micro air refrigerator, the micro air refrigerator is arranged at the tail end of the main pipeline, and the micro air refrigerator and the inflator are connected with the main pipeline through a tee joint;

the branch pipes of the tee joint, which are connected with the micro air cooler and the aerator, are respectively provided with an electromagnetic valve, so that the micro air cooler and the aerator are respectively connected with the main pipeline through the electromagnetic valves;

the upper surface of the filler is provided with 24 body temperature sensors, and the 24 body temperature sensors are uniformly distributed in four rows along the longitudinal center line of the mattress;

the upper surface of the filler is provided with a sensor mounting hole, the periphery of the body temperature sensor is mounted in the sensor mounting hole through a heat insulation silica gel plug, the tail part of the body temperature sensor is mounted in the sensor mounting hole, the temperature sensing head part of the body temperature sensor is exposed out of the outer side of the fabric to sense the body temperature of a sleeper, and an electric wire led out from the tail part of the body temperature sensor penetrates through the heat insulation silica gel plug to be connected to the control module; the upper surface of the filler is provided with a groove, and the groove is used for placing an electric wire led out from the tail part of the body temperature sensor;

an environment temperature sensor is arranged on the side surface of the spring bed net and connected with the control module and used for collecting the current environment temperature;

the method is characterized by comprising the following steps:

(1) the sleeper adjusts the air pressure of each transverse air bag through the electromagnetic valve and the exhaust valve according to the corresponding relation between the transverse air bag serial number and the sleeper profile, so that the sleeper can freely adjust the air pressure of the air bags of each part according to the actual support requirement of each part of the body;

(2) the air pressure of the air bags in all rows is adjusted during the sleeping process of the sleeper; judging the current sleeping position of the sleeper and the number of the transverse rows where the air bags pressed by the sleeper in the current sleeping posture are located through the pressure sensor array; the sleeper respectively adjusts the temperature of each transverse row through the electric heater and the temperature sensor according to the temperature requirements of the sleeper on different parts of the body, so that the sleeping temperature of the sleeper is controlled in a partition mode;

if the sleeper feels that the preset temperature of the air bag of a certain row is too high, the temperature of the air bag can be reduced through an exhaust valve, an electromagnetic valve and an inflator, namely, the control module controls the exhaust valve, the electromagnetic valve and the inflator to be opened simultaneously, and new air is blown into the branch pipeline of the row to extrude the original hot air to reduce the temperature of the row;

(3) before the sleeper sleeps, the number of the current sleeping position and the number of the transverse row where the air bag pressed by the current sleeping posture is located are obtained through the pressure sensor array; according to the sleeping position and the airbag number of the sleeper, the sleeper presets the refrigeration temperature values of all rows; the control module arranges the temperature values of all rows preset by the sleeper from high to low; the control module closes the electromagnetic valve on the branch of the inflator on the tee joint and opens the electromagnetic valve on the branch of the micro air refrigerator; the control module controls the micro air cooler to sequentially convey the cold air to each row according to the sequence of temperature values from high to low, and in the process of cold air conveying, a sleeper determines the air pressure in each transverse branch pipeline according to the memory of an air pressure mode or the self perception so as to determine the stop of the cold air conveying;

if the sleeper senses that the temperature in the transverse air bag is too high in the refrigerating process and needs to be continuously refrigerated, the temperature of the re-walking air bag is continuously reduced through the cooperation of the exhaust valve, the electromagnetic valve and the micro air refrigerator; if the sleeper senses that the temperature in the transverse air bag is too low and needs to be increased, the electric heater is controlled by the control module to be properly heated, so that the transverse temperature is increased;

(4) in the sleeping process of the sleeper, judging the current sleeping position of the sleeper through the pressure sensor array; according to the sleeping position, starting the body temperature sensor closest to the body temperature sensor along the central axis of the sleeping position in each row of the body temperature sensors to respectively obtain the temperature values of the body temperature sensors; comparing the temperature values with the environment temperature values measured by the environment temperature sensors respectively, and if the temperature difference between the temperature values exceeds the threshold range, indicating that the sleeper kicks a quilt and the area where the body temperature sensor corresponding to the temperature value is located is exposed in the air; at this time, the control module can control the transverse movement of the area where the body temperature sensor is located to heat so as to prevent the sleeper from catching a cold.

2. The use method of the energy-saving mattress according to claim 1, wherein an air pressure sensor is arranged in each horizontal branch pipe, the air pressure sensor can monitor the air pressure value in each horizontal line and can store the measured air pressure value in a memory to realize the memory of the air pressure mode.

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