CN216358462U - Bed mattress with self-adjusting heating function - Google Patents

Abstract

The utility model is suitable for the technical field of bedding, and provides a bedding with a self-adjusting heating function, which comprises a first set of heating components consisting of nano-carbon electric heating wires, wherein a second set of heating components consisting of infrared heating wires are arranged above the first set of heating components, and the first set of heating components and the second set of heating components are turned over through side edges and are selected for use. The difference between the first set of heating elements and the second set of heating elements is that the first set of heating elements can be used as a small single-person scene and a double-person separated scene; the second set of heating components can be used for large single-person scenes and double-person non-separated scenes, automatic selection of various different scenes is increased, and the system is more humanized. Meanwhile, the automatic temperature changer which automatically controls temperature change is matched to change the temperature of the first set of heating assembly and the second set of heating assembly, so that manual adjustment of a user is avoided, the function of automatic temperature adjustment is realized, and electric energy can be effectively saved.

Description

Bed mattress with self-adjusting heating function

Technical Field

The utility model belongs to the technical field of bedding, and particularly relates to a bedding with a self-adjusting heating function.

Background

Quilt and cotton-padded mattress, and cover. Is as follows: quilt, cotton quilt for covering body during sleeping. The warm-keeping and cold-resisting article is generally made of cloth or silk fabric as a surface, the cloth as a lining and cotton, silk floss or down feather and the like in the lining, and is covered on the body when sleeping; bedding: a mattress and a quilt which is made of cotton wool, animal hide or electric heating materials and the like and is padded under the body during sleeping.

The heating element is all laid to whole quilt to current bed clothes that can generate heat, causes the waste of electric energy, and current double quilt is when using in addition, and the interval leaves a large amount of clearances between the double, leads to the quick loss of inside air, and then leads to whole bed clothes to need frequent heating, also causes the waste of electric energy.

SUMMERY OF THE UTILITY MODEL

The utility model provides a bed mattress with a self-adjusting heating function, and aims to solve the problems that heating elements are paved on the whole quilt of the existing bed mattress capable of heating, so that electric energy is wasted, and a large number of gaps are reserved between two people when the existing double quilt is used, so that the internal air is rapidly lost, the whole bed mattress needs to be heated frequently, and the electric energy is wasted.

The utility model is realized in such a way that the bedding with the self-adjusting heating function comprises a first set of heating components consisting of nano-carbon electric heating wires, a second set of heating components consisting of infrared heating wires are arranged above the first set of heating components, the first set of heating components and the second set of heating components are turned over through the side edges and are used alternatively, and the first set of heating components and the second set of heating components are controlled by an automatic temperature changer to automatically change the temperature.

Preferably, the nanocarbon heating wires in the first set of heating components are arranged in a multi-channel S shape, the nanocarbon heating wires are located near the middle shaft of the mattress and used for a single person, and the nanocarbon heating wires are pulled by the multi-channel pull ropes located on two sides to be unfolded towards the two sides and used for a double person.

Preferably, the pull ropes of the left and right parts are staggered and spaced in an S shape, and the pull ropes of the left and right parts are respectively gathered into one at the edges of the left and right sides for manual pulling, tightening and adjusting.

Preferably, the inner sides of the plurality of S-shaped nano-carbon electric heating wires and the parts staggered with the pull ropes are provided with air cavity branch channels, and the air cavity branch channels are communicated with an air cavity main channel at the central axis of the mattress.

Preferably, the second set of heating elements comprises infrared heating wires arranged in a vortex shape inside, and the outer part is a shell obtained by performing fabric after-treatment on the fiber fabric through working solution containing capsicum tincture extract finishing agent, nonionic organosilicon softening agent and nano ceramic powder dispersion liquid.

Preferably, one side of the outer surfaces of the first set of heating element and the second set of heating element is fixed together, and the other three sides are fixed together through a zipper.

Preferably, the automatic temperature changer comprises a plurality of sensors arranged on the surfaces of the first set of heating component and the second set of heating component, the sensors send real-time detected temperature and ambient conditions to the automatic temperature changer, and the automatic temperature changer automatically adjusts the nano-carbon heating wires of the first set of heating component and the infrared heating wires of the second set of heating component which are electrically connected with the automatic temperature changer according to an internal data model.

Compared with the prior art, the utility model has the beneficial effects that: according to the bedding with the self-adjusting heating function, the first set of heating component and the second set of heating component are different in that the first set of heating component can be used as a small single-person scene and a double-person separated scene; the second set of heating components can be used for large single-person scenes and double-person non-separated scenes, automatic selection of various different scenes is increased, and the system is more humanized.

The automatic temperature changer that cooperates automatic control temperature change simultaneously carries out the change of temperature to first set of heating element and second set of heating element, avoids the artificial regulation of user, and the function of automatic temperature regulation can effectual saving electric energy, selects saving electric energy that corresponding sight can be better simultaneously.

Drawings

FIG. 1 is a schematic view of the overall internal structure of the present invention;

FIG. 2 is a schematic diagram of a power control curve according to the present invention.

In the figure: 1. a first set of heating elements; 11. a nano-carbon heating wire; 12. pulling a rope; 13. an air cavity main channel; 14. An air cavity branch channel; 2. a second set of heating elements; 21. an infrared heating wire; 22. a housing; 3. an automatic temperature changer; 31. a sensor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a bed mattress with self-interacting function of generating heat, includes first set of heating element 1 that nanocarbon heating wire 11 is constituteed, sets up second set of heating element 2 of constituteing by infrared heating wire 21 in the top of first set of heating element 1, and first set of heating element 1 and second set of heating element 2 pass through the side upset, and the alternative is used, and first set of heating element 1 and second set of heating element 2 are controlled its temperature automatic change by automatic temperature changer 3.

The difference between the first set of heating elements 1 and the second set of heating elements 2 is that the first set of heating elements 1 can be used as a small single-person scenario and a double-person separated scenario; the second set of heating elements 2 may be used in a large single person scenario as well as a double person non-segregated scenario.

Meanwhile, the automatic temperature changer 3 which automatically controls the temperature change is matched to change the temperature of the first set of heating component 1 and the second set of heating component 2, so that the manual regulation of a user is avoided, and the automatic use situation and the application range are increased.

The nano-carbon heating wires 11 in the first set of heating assembly 1 are arranged in a multi-channel S shape, the nano-carbon heating wires 11 are located near the central axis of the mattress and used for a single person, and the nano-carbon heating wires 11 are pulled by the multi-channel pull ropes 12 located at two sides to be unfolded towards the two sides and used for a double person. The pull ropes 12 are arranged on the left part and the right part, the pull ropes 12 on the left part and the right part are staggered and spaced in an S shape, and the pull ropes 12 on the left part and the right part are respectively gathered into one at the edges of the left side and the right side for manual pulling, tightening and adjusting.

The back both sides respectively are provided with stay cord 12 after S-shaped nanometer carbon heating wire 11' S corner interval staggers, expand nanometer carbon heating wire 11 through stay cord 12, expand its whole area, the scope of using has been increased and both ends are converged into respectively, the unified pulling of person of facilitating the use is adjusted, wait to confirm to tie a knot after the distance and avoid being pulled the recovery by the air cavity reversal as blockking, when recovering, only need loosen the department of tying a knot, pat air cavity department, can resume the normal position with whole nanometer carbon heating wire 11.

The inner side of the plurality of S-shaped nano-carbon electric heating wires 11 and the part staggered with the pull rope 12 are provided with air cavity branch channels 14, and the plurality of air cavity branch channels 14 are all communicated with an air cavity main channel 13 at the central axis of the mattress.

Air cavity subchannel 14 is provided with a plurality ofly respectively in the S-shaped corner of each nanometer carbon heating wire 11 to when stay cord 12 pulling nanometer carbon heating wire 11 part moves outward, its adjacent part is by the inside indentation of reverse pulling, and then extrudees the air cavity main road 13 in each air cavity subchannel 14, forms strip arch in air cavity main road 13, and then cuts off double bed clothes, be used for blockking in the middle of the double, avoid the loss of air.

Preferably, the air cavity branch channel 14 and the air cavity main channel 13 can also contain liquid inside, and the heat dissipation speed of the liquid is lower than that of normal air, so that the air cavity branch channel and the air cavity main channel are used for keeping warm for a long time, but the weight of the whole bedding is increased, the air cavity branch channel and the air cavity main channel are not convenient to use, but are positioned in the middle of two people and do not have great influence.

The second set of heating element 2 comprises an infrared heating wire 21 arranged in a vortex shape inside, and an outer shell 22 is obtained by performing fabric after-treatment on a fiber fabric through working solution containing a capsicum tincture extract finishing agent, a nonionic organosilicon softening agent and a nano ceramic powder dispersion liquid.

The fabric finishing agent is obtained by carrying out fabric after-finishing on a fiber fabric through the working solution containing the capsicum tincture extract finishing agent, the nonionic organosilicon softening agent and the nano ceramic powder dispersion liquid, has the functions of radiating far infrared rays to a human body, warming, heating and health care, and has better fixation of the capsicum tincture extract on the fabric, so that the efficacy is not easy to reduce along with washing; the adopted capsicum tincture extract finishing agent can be a capsicum tincture extract finishing agent TaSTEXHOT2 produced by Bayer Japan company, which is prepared by taking capsicum extract and chamomile extract as main raw materials and matching with undecylenic acid monoglyceride and the like. Because the extracts take the capsicum tincture as the main component, the capsicum tincture is generally used for the ointment for treating joint ache, and the oil-water combined finishing agent is applied to dyeing and finishing processing, so that the capsicum tincture is used for promoting blood circulation and metabolism and generating heat storage and warm keeping effects.

The specific treatment process of the shell 22 fabric after finishing the weaving of the fabric comprises the following steps: grey cloth → singeing → scouring → bleaching → heat setting → sanding → dyeing → warm sense finishing → soft finishing.

The method of 'CN 201210112828.7 a fiber fabric with heating function and the preparation method thereof' is adopted, and the yarns are selected: 30 English counts of blended yarn of 30% of kapok fiber and 70% of soft silk protein regenerated fiber are selected as warp yarn, and 21 English counts of blended yarn of 30% of kapok fiber and 70% of soft silk protein regenerated fiber are selected as weft yarn. The kapok fiber has the advantages of low density, good moisture absorption and moisture permeability, soft hand feeling and warm and smooth touch, but the kapok fiber has shorter length and lower strength and poor cohesion. The soft silk protein fiber not only has the advantages of bright and soft luster, good moisture absorption and desorption, good fiber softness, good fabric drapability and the like, but also has the health-care functions of absorbing ultraviolet rays, far infrared rays, negative oxygen ions and the like. The soft silk fiber has long length and good uniformity, can make up for the deficiencies of the blended cotton fiber, and is green and environment-friendly fiber yarn.

Weaving: for the blended yarn of the kapok fiber and the soft silk protein fiber, twill weave with three over one under is adopted, the warp and weft interweaving density is 133 multiplied by 60/inch, and grey cloth is obtained on a rapier loom.

Boiling: the high-efficiency scouring agent TF-1884 (chemical industry) is 4 g/L, the processing temperature is 80 ℃, the heat preservation time is 60min, and then the water washing is carried out.

Bleaching: 2 g/L of hydrogen peroxide (35%), 2 g/L of sodium hydroxide and 1 g/L of oxygen bleaching stabilizer (chemical engineering), the initial setting is 50 ℃, the heating rate is 1 ℃/min, the heating is carried out to 80 ℃, the heat preservation is carried out for 60min, the mixture is washed by hot water, 0.5ml/L of acetic acid (30%) is added for cold neutralization, and then the mixture is washed by cold water.

Heat setting: temperature: 160 ℃ for 30 s.

Sanding: adopts a carbon fiber sanding process, and belongs to the known technical field.

Preparing a thermal sense finishing agent:

tastexhot2 capsicum tincture micelle compound (Bayer Japan Co., Ltd.) 10 g/l

Nonionic organosilicon softening agent (ultratexFSA of Ciba Geigy) 5 g/L

Nano ceramic powder dispersion (JR-YHL01, Xuancheng Crystal-Rui New Material Co., Ltd.) 50 g/L

Fabric after finishing: the method is carried out by padding. The finishing process by the padding method comprises the following steps: preparing 30L of thermal sense finishing agent according to the proportion, soaking the fabric, carrying out two-time rolling with the rolling residual rate of 70%, drying at 130 ℃, and shaping.

Softening and finishing: 30 g/l super soft amino silicone oil emulsion TF-455, bath ratio: 1: 30, drying at 100 ℃, and then baking at 160 ℃ for 45 s.

One side surface of the outer surfaces of the first set of heating component 1 and the second set of heating component 2 is fixed together, and the other three side surfaces are fixed together through zippers.

The automatic temperature changer 3 comprises a plurality of sensors 31 arranged on the surfaces of the first set of heating component 1 and the second set of heating component 2, the sensors 31 send the real-time detected temperature and the ambient environment condition to the automatic temperature changer 3, and the automatic temperature changer 3 automatically adjusts the nano-carbon heating wires 11 of the first set of heating component 1 and the infrared heating wires 21 of the second set of heating component 2 which are electrically connected with the automatic temperature changer according to an internal data model.

The automatic temperature changer 3 adopts a mode of 'CN 202011553466.6 a method for adjusting the heating temperature of an electric blanket based on an external controller', and the temperature in the bedding is not only related to the power of the electric blanket, but also related to the environmental temperature and the thickness of the bedding; therefore, in this embodiment, the following means is adopted to establish the conversion relationship between the power percentage and the temperature in the bedding:

firstly, selecting a plurality of existing electric blankets and respectively connecting the electric blankets in series with external controllers in a standard room;

then, respectively detecting the corresponding internal temperature of the bedding by adopting a temperature detector or a thermocouple under different environmental temperatures, different bedding thicknesses and different power percentages (for more accuracy, the average temperature can be taken); the 'different power percentages' can control the power percentage output of the electric blanket according to the duty ratio of the PWM wave of the external controller;

then, establishing a relation between the power percentage of the external controller and the temperature in the bedding when the electric blanket works by combining the ambient temperature of the electric blanket and the thickness of the bedding; although the heating devices of the electric blanket are not uniformly distributed, the temperature in the bedding at the initial stage is not uniform, and finally, a uniform temperature field is obtained after the temperature is stabilized, so that the internal temperature of the bedding is assumed to be uniform;

then, based on the test data of the previous step, combing the relation between the power percentage of a plurality of external controllers and the temperature in the bedding when the electric blanket works, and as a power control curve is formed, fitting calculation is carried out on the data: t is (K1T ring + K2H by) P power percentage; t is: the obtained temperature in the bedding; k1: a coefficient related to ambient temperature; and (3) ring T: ambient temperature; k2: a coefficient related to the thickness of the bedding; h is: thickness of the bedding; percentage of P power: percentage of power input by the controller.

A more generally applicable power control curve is obtained as shown in fig. 2, and it can be seen from fig. 2 that the temperature in the bedding is substantially linear with the power percentage.

And finally, implanting the fitted power control curve into an external controller.

In order to further improve the accuracy of temperature control, the thickness of the bed sheet or mattress wadding between the human body and the electric blanket can be taken into consideration as a parameter, namely, the temperature relationship of the bedding when the electric blanket is operated according to different power percentages under different environmental temperatures, different bedding thicknesses and different mattress wadding or bed sheet thicknesses between the electric blanket and the human body is established.

After a sleep curve and the power control curve are preset in the external controller, the temperature in the bedding can be dynamically adjusted by combining the sleep curve and the power control curve: the external controller obtains the target temperature of the bedding corresponding to the current sleep stage according to the sleep curve; searching control power corresponding to the ambient temperature and the thickness of the bedding in the power control curve according to the target temperature of the bedding; and controlling the electric blanket according to the obtained control power so as to obtain the proper temperature in the bedding.

If the user is not satisfied with the sleep curve, the target temperature in the bedding which is expected to be set can be adjusted through the mobile phone app in wireless communication with the external controller or the remote controller matched with the external controller or the keys of the external controller body, so that the sleep curve is adjusted. Since the user directly adjusts the temperature value, it is more intuitive and easier to understand than adjusting the control power value or power percentage.

The working principle and the using process of the utility model are as follows:

when the first set of heating component 1 is positioned below, the second set of heating component 2 is positioned above, the first set of heating component 1 is used, when the first set of heating component 1 is used by a single person, the first set of heating component 1 is normally laid on a human body and the automatic temperature changer 3 is started to electrify and heat the nano-carbon heating wire 11 in the first set of heating component 1, so that the single person is heated in a heat-preserving way; when the first set of heating assembly 1 is used by a single person, the user pulls the pull ropes 12 positioned at the left side and the right side, the nano-carbon heating wire 11 is pulled to the left side and the right side, the nano-carbon heating wire 11 is unfolded along the bed mattress, meanwhile, the inner side part of the nano-carbon heating wire 11 is pulled and recovered, and then the inner side air cavity branch channel 14 is extruded, so that the nano-carbon heating wire flows into the air cavity main channel 13 in the air cavity branch channel 14, a strip-shaped protruding partition is formed in the middle of the whole bed mattress, certain interval is further performed in the middle of two persons, the middle of the two persons is blocked, hot air leakage at the interval between the two persons is avoided, then the nano-carbon heating wire 11 in the first set of heating assembly 1 is normally laid on the left and right two human bodies, the automatic temperature changer 3 is started, the nano-carbon heating wire 11 in the first set of heating assembly 1 is electrified to generate heat, and the two persons are subjected to heat preservation and heating after being separated at the interval.

When the second set of heating components 2 is positioned below, the first set of heating components 1 is positioned above, the second set of heating components 2 is used, the automatic temperature changer 3 is powered on, the infrared heating wires 21 are controlled by the automatic temperature changer 3 to heat, and then the bedding is manually covered on a human body for normal use.

When the first set of heating component 1 and the second set of heating component 2 are switched; in the same way of pulling the quilt cover or the luggage case open, firstly, two zippers are respectively pulled at two sides, the two zippers are directly pulled to the opposite tail ends to stop, then the first set of heating component 1 and the second set of heating component 2 are turned over for the broken edges, so that the inner face and the outer face are turned over, then the zippers at the two sides are pulled again to carry out encapsulation again, and the first set of heating component 1 and the second set of heating component 2 are exchanged in the up-down direction of the position.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (7)

1. A bed mattress with self-adjusting heating function, its characterized in that: including first set of heating element (1) that nanocarbon heating wire (11) is constituteed the top of first set of heating element (1) sets up second set of heating element (2) of constituteing by infrared heating wire (21), first set of heating element (1) with second set of heating element (2) are through the side upset, and the alternative is used, first set of heating element (1) and second set of heating element (2) are controlled its temperature automatic change by automatic temperature changer (3).

2. The mattress with self-regulating heating function of claim 1, wherein: the nano-carbon heating wires (11) in the first set of heating assembly (1) are arranged into a plurality of S shapes, the nano-carbon heating wires (11) are positioned near the central axis of the mattress and used for a single person, and the nano-carbon heating wires (11) are pulled by a plurality of pull ropes (12) positioned at two sides and unfolded towards the two sides for a double person to use.

3. The mattress with self-regulating heating function of claim 2, wherein: the pull rope (12) comprises a left portion and a right portion, the pull ropes (12) of the left portion and the right portion are staggered and spaced in an S shape, and the pull ropes (12) of the left portion and the right portion are respectively converged into one at the edges of the left side and the right side for manual pulling, tightening and adjusting.

4. A mattress with self-regulating heating function according to claim 3, characterized in that: and air cavity branch channels (14) are arranged on the inner sides of the plurality of S-shaped nano-carbon electric heating wires (11) and staggered with the pull ropes (12), and the air cavity branch channels (14) are communicated with an air cavity main channel (13) at the central axis of the mattress.

5. The mattress with self-regulating heating function of claim 1, wherein: the second set of heating component (2) comprises infrared heating wires (21) which are arranged in a vortex shape, and the outer part is a shell (22) obtained by carrying out fabric after-treatment on the fiber fabric through working solution containing capsicum tincture extract finishing agent, nonionic organosilicon softening agent and nano ceramic powder dispersion liquid.

6. The mattress with self-regulating heating function of claim 1, wherein: one side surface of the outer surfaces of the first set of heating component (1) and the second set of heating component (2) is fixed together, and the other three side surfaces are fixed together through zippers.

7. The mattress with self-regulating heating function of claim 1, wherein: automatic temperature changer (3) including being provided with first set of heating element (1) with a plurality of sensors (31) on second set of heating element (2) surface, this sensor (31) send real-time detection's temperature and surrounding environment condition for automatic temperature changer (3), automatic temperature changer (3) according to inside data model automatically regulated rather than electric connection's first set of heating element (1) nanometer carbon heating wire (11) and second set of heating element (2) infrared heating wire (21).

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