CN215347972U - Graphite alkene intelligence mattress and system that generates heat - Google Patents

Abstract

The utility model discloses a graphene intelligent heating mattress, which comprises: the mattress comprises a mattress body, at least one group of heating sensing modules and a control box, wherein the heating sensing modules are packaged in the mattress body and are connected with the control box; every group sensing module that generates heat includes that main graphite alkene generates heat the area, temperature sensor, at least a slice pair graphite alkene generates heat and takes and at least one temperature detect switch, and main graphite alkene generates heat and takes and to connect in parallel each other and main graphite alkene generates heat and takes, vice graphite alkene generates heat and takes, temperature sensor and temperature detect switch are connected with the control box respectively with vice graphite alkene, and temperature sensor locates on the main graphite alkene generates heat and takes one-to-one and temperature detect switch locates on the vice graphite alkene of correspondence of temperature detect switch and vice graphite alkene. The utility model also discloses a graphene intelligent heating mattress system. By adopting the utility model, the mattress body can be ensured to uniformly heat, the user experience is improved, the structure is simple, and the safety is high.

Description

Graphite alkene intelligence mattress and system that generates heat

Technical Field

The utility model relates to the technical field of mattresses, in particular to a graphene intelligent heating mattress and a graphene intelligent heating system.

Background

With the improvement of living standard, people do not rely on thick and heavy bedding in cold winter, and are more willing to put into the household appliances, and the heating mattress can heat through self electric heating, and the heating mattress is an effective means for sleeping and heating in winter. In the prior art, the heating mattress mainly adopts the traditional thermal resistance type heating mattress, but the thermal resistance type heating mattress has poor temperature controllability and low circuit safety, and related reports of fire disasters and the like caused by the thermal resistance type heating mattress are frequently used.

However, due to the development of graphene technology, graphene heating mattresses are also increasingly widely used. Graphene is a material with the most application potential in the twenty-first century, and the ultrahigh electrical conductivity and the ultrahigh mechanical strength and toughness of graphene leave a deep impression. At present, the patents related to graphene mattresses are more and more, but the products related to the patents only convert electric energy into heat energy after graphene is used as an additive to form a conductive film, and the conductive film completely covers the mattress to form a whole, so that people resting on the mattress are easy to interfere with each other; meanwhile, the existing graphene heating mattress is complex in structural design, has potential safety hazards, and cannot meet the actual requirements of users.

SUMMERY OF THE UTILITY MODEL

The graphene intelligent heating mattress provided by the utility model has the advantages that the structure is simple, the safety is high, the uniform heating of the mattress body can be ensured, and the user experience is improved.

The technical problem to be solved by the utility model is also to provide the graphene intelligent heating system, which can realize wireless control and has high intelligent degree.

In order to solve the technical problem, the utility model provides a graphene intelligent heating mattress which comprises a mattress body, at least one group of heating sensing modules and a control box, wherein the heating sensing modules are packaged in the mattress body and are connected with the control box; every group sensing module that generates heat includes that main graphite alkene generates heat area, temperature sensor, at least a slice pair graphite alkene generate heat and take and at least one temperature detect switch, main graphite alkene generate heat take with vice graphite alkene generate heat take each other parallelly connected just main graphite alkene generate heat area, vice graphite alkene generate heat area, temperature sensor and temperature detect switch respectively with the control box is connected, temperature sensor locates on the main graphite alkene generates heat takes, temperature detect switch with vice graphite alkene generate heat take one-to-one just temperature detect switch locates on the vice graphite alkene generate heat of correspondence and takes.

As an improvement of the above scheme, the graphene intelligent heating mattress further comprises a flame-retardant pad packaged in the mattress body, the flame-retardant pad comprises an upper flame-retardant layer and a lower flame-retardant layer, and the heating sensing module is embedded between the upper flame-retardant layer and the lower flame-retardant layer.

As an improvement of the scheme, the main graphene heating belt and the auxiliary graphene heating belt are sequentially arranged along the length direction of the mattress body.

As the improvement of above-mentioned scheme, graphite alkene intelligence mattress that generates heat include the two sets of sensing module that generate heat that set up side by side along the width direction of mattress body.

As an improvement of the scheme, the distance between the main graphene heating strips and the distance between the auxiliary graphene heating strips in different groups of heating sensing modules are 5-15cm, and the distance between the adjacent main graphene heating strips and/or the auxiliary graphene heating strips in the same group of heating sensing modules is 20-25 cm.

As an improvement of the above scheme, the temperature sensor is connected with the control box through a signal line, and the main graphene heating belt, the auxiliary graphene heating belt and the temperature control switch are respectively connected with the control box through power lines.

As an improvement of the above scheme, the graphene intelligent heating mattress further comprises a power adapter, and the control box is connected with an external power supply through the power adapter.

As an improvement of the scheme, the control box is connected with the power adapter through a connector, and a nut used for fixing is arranged on the connector.

As an improvement of the scheme, the heating sensing module is connected with the control box through a USB interface.

Correspondingly, the utility model further provides a graphene intelligent heating system which comprises control equipment and the graphene intelligent heating mattress, wherein the control equipment is in communication with the graphene intelligent heating mattress in a wireless mode.

The beneficial effects of the implementation of the utility model are as follows:

according to the utility model, by arranging a plurality of mutually independent strip-shaped graphene heating belts (including the main graphene heating belt and the auxiliary graphene heating belt), the phenomenon that the heat at the central position is too high due to too large heating area can be avoided, and the uniform heating of the mattress body can be ensured.

Furthermore, the flame-retardant pad is arranged, so that the heating sensing module is effectively packaged, and the safety is high.

In addition, the power adapter and the control box adopt a split type design, are connected and fixed by combining the connector with the screw cap, are flexible to disassemble and convenient to assemble, and can improve the anti-pulling and waterproof effects.

Drawings

Fig. 1 is a schematic structural diagram of a graphene intelligent heating mattress according to a first embodiment of the utility model;

fig. 2 is a schematic structural diagram of a control box and a power adapter in the graphene intelligent heating mattress of the utility model;

FIG. 3 is a schematic structural diagram of a joint in the graphene intelligent heating mattress according to the utility model;

fig. 4 is a schematic structural diagram of a graphene intelligent heating mattress according to a second embodiment of the present invention;

fig. 5 is a schematic structural diagram of an embodiment of the graphene intelligent heating system of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, fig. 1 shows a first embodiment of the graphene intelligent heating mattress of the present invention, which includes a mattress body, a heating sensing module 1 and a control box 2 (see fig. 2), wherein the heating sensing module 1 is encapsulated in the mattress body, and the heating sensing module 1 is connected to the control box 2. The heating sensing module 1 comprises a main graphene heating belt 11, a temperature sensor 12, at least one auxiliary graphene heating belt 13 and at least one temperature control switch 14; the main graphene heating strip 11 and the auxiliary graphene heating strip 13 are connected in parallel, and the main graphene heating strip 11, the auxiliary graphene heating strip 13, the temperature sensor 12 and the temperature control switch 14 are respectively connected with the control box 2; the temperature sensor 12 is arranged on the main graphene heating belt 11 and used for monitoring the heating temperature of the main graphene heating belt 11 in real time; the temperature control switch 14 with vice graphite alkene generates heat and takes 13 one-to-one just temperature control switch 14 locates on the vice graphite alkene of correspondence generates heat and takes 13, is used for the control the heating temperature of vice graphite alkene generate heat and take 13 and switch on or break off vice graphite alkene generates heat and takes 13, guarantees vice graphite alkene and generates heat the safe operation in area 13.

In the prior art, the graphene conductive film only covers the mattress completely. Different from the prior art, the heating device comprises a main graphene heating belt 11 and at least one auxiliary graphene heating belt 13, the main graphene heating belt 11 and the auxiliary main graphene heating belt 11 are both in a belt shape, the main graphene heating belt 11 and the auxiliary main graphene heating belt 11 are independent and separated from each other, and the phenomenon that the heat at the central position is too high due to the fact that the heating area is too large can be avoided.

In the utility model, the length of the main graphene heating belt 11 and the width of the auxiliary main graphene heating belt 11 are 45-65cm and 8-12cm, so that a belt-shaped structure is formed, and materials can be greatly saved while heating. In this embodiment, the length of the main graphene heating strip 11 and the auxiliary main graphene heating strip 11 is preferably 50cm, and the width thereof is preferably 10cm, so that the comfort of a single user can be ensured.

In addition, in the utility model, the main graphene heating strips 11 and the auxiliary graphene heating strips 13 are sequentially arranged along the length direction of the mattress body, so that the mattress body can be ensured to uniformly heat. Correspondingly, the distance D1 between the adjacent main graphene heating strips 11 and the auxiliary graphene heating strips 13 and the distance D1 between the adjacent auxiliary graphene heating strips 13 are 20-25cm, and the distance is reserved, so that the heat of a heating point has a sufficient diffusion space, the heat is prevented from being excessively concentrated, and a more comfortable user experience is provided, wherein in the embodiment, the distance between the adjacent main graphene heating strips 11 and the auxiliary graphene heating strips 13 and the distance between the adjacent auxiliary graphene heating strips 13 are preferably 23 cm.

Accordingly, the temperature sensor 12 is connected to the control box 2 through a signal line, wherein the temperature sensor 12 is preferably an NTC sensor, and the signal line is preferably an NTC signal line, but not limited thereto, as long as accurate temperature monitoring can be achieved;

in addition, the main graphene heating belt 11, the auxiliary graphene heating belt 13 and the temperature control switch 14 are respectively connected with the control box 2 through power lines. It should be noted that the power cord includes positive pole line and negative pole line, control box 2 connects respectively through positive pole line and negative pole line main graphite alkene generates heat and takes 11, vice graphite alkene generates heat and takes 13 and temperature detect switch 14, and in this embodiment, the electric current of flowing through of power cord is 3A, and voltage is 24V to guarantee that main graphite alkene generates heat and takes 11 and vice graphite alkene to generate heat the maximum current in area 13 and not more than 3A, guarantee user safety, reduce the power consumption hidden danger.

Correspondingly, in the utility model, the heating sensing module 1 is connected with the control box 2 through the USB interface 21 (see FIG. 2), so that the plugging and pulling are convenient and the flexibility is strong.

Further, the graphene intelligent heating mattress further comprises a flame-retardant pad 3 packaged in the mattress body, in the embodiment, the length of the flame-retardant pad 3 is 150cm, the width of the flame-retardant pad is 75cm, and the comfort level of a single person in use can be guaranteed; meanwhile, the flame-retardant pad 3 comprises an upper flame-retardant layer and a lower flame-retardant layer, the heating sensing module 1 is embedded between the upper flame-retardant layer and the lower flame-retardant layer, the upper flame-retardant layer and the lower flame-retardant layer are both thin flame-retardant fabrics, and the thickness of the graphene intelligent heating mattress can be effectively reduced. Therefore, after the packaging of the flame retardant pad 3, the heat-generating sensing module 1 is completely isolated in the flame retardant pad 3, and only the signal line and the power line extend out of the flame retardant pad 3 to be connected with the control box 2, so that the safety is high.

As shown in fig. 2, the graphene intelligent heating mattress further comprises a power adapter 4, and the control box 2 is connected with an external power supply through the power adapter 4.

As shown in fig. 3, the control box 2 is connected to the power adapter 4 through a connector 5, and a nut 51 for fixing is provided on the connector 5.

It should be noted that, in the utility model, the power adapter 4 and the control box 2 adopt a split design, which can be flexibly disassembled and assembled and is convenient for replacing components; meanwhile, the nut 51 fixes the joint 5, so that the anti-pulling and waterproof effects can be improved.

Therefore, by arranging a plurality of mutually independent strip-shaped graphene heating bands (comprising the main graphene heating band 11 and the auxiliary graphene heating band 13), the utility model can avoid overhigh heat at the central position due to overlarge heating area and ensure that the mattress body can uniformly heat; meanwhile, the flame-retardant pad 3 is arranged, so that the heating sensing module 1 is effectively packaged, and the safety is high; in addition, the power adapter 4 and the control box 2 adopt a split design, and are connected and fixed by combining the connector 5 with the screw cap 51, so that the disassembly is flexible, the assembly is convenient, and the anti-pulling and waterproof effects can be improved.

Referring to fig. 4, fig. 4 shows a second embodiment of the graphene intelligent heating mattress of the present invention, which is different from the first embodiment shown in fig. 1 in that two sets of heating sensing modules 1 are included in the present embodiment and are arranged side by side along the width direction of the mattress body.

It should be noted that, by arranging two sets of heating sensing modules 1, a double-control mode of the mattress can be realized. That is to say, through the temperature of adjusting two sets of sensing module 1 that generate heat, can make two sets of sensing module 1 that generate heat the temperature difference, the flexibility of the double use of laminating more.

Further, the distances D2 between the main graphene heating strips 11 and between the auxiliary graphene heating strips 13 in different groups of heating sensing modules 1 are 5-15cm, so that the mutual influence of the temperatures of different heating sensing modules 1 can be avoided.

Correspondingly, in this embodiment, the distance between the main graphene heating strips 11 and the distance between the auxiliary graphene heating strips 13 in different groups of heating and sensing modules 1 are 10cm, the length of each main graphene heating strip 11 and each auxiliary main graphene heating strip 11 is 60cm, the width of each main graphene heating strip is 10cm, the distance between the adjacent main graphene heating strips 11 and the adjacent auxiliary graphene heating strips 13 and the distance between the adjacent auxiliary graphene heating strips 13 are 23cm, and the comfort level of the two users can be ensured; meanwhile, in the embodiment, the length of the flame retardant pad 3 is 150cm, the width of the flame retardant pad is 75cm, the main graphene heating strip 11 and the auxiliary main graphene heating strip 11 can be completely packaged, and the safety is high; in addition, in this embodiment, the current that flows through of power cord is 5A, and voltage is 24V, can effectively guarantee that the maximum current of main graphite alkene heating zone 11 and vice graphite alkene heating zone 13 does not exceed 5A, guarantees user's safety, reduces the power consumption hidden danger.

As shown in fig. 5, the utility model also discloses a graphene intelligent heating system, which comprises a control device and a graphene intelligent heating mattress, wherein the control device communicates with a control box 2 in the graphene intelligent heating mattress in a wireless manner, so that monitoring of the graphene intelligent heating mattress is realized.

The controller can be a remote controller 6, a mobile phone 7, a tablet computer and the like. Wherein, can realize the closely control to graphite alkene intelligence mattress that generates heat through remote controller 6, and then can realize the remote control to graphite alkene intelligence mattress that generates heat through mobile devices such as cell-phone 7, panel computer, convenient operation, intelligent degree is high.

Correspondingly, the wireless mode includes convenience such as bluetooth, WIFI, nevertheless does not regard this as the restriction, as long as can realize the intelligent networking of controlgear.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the utility model.

Claims (10)

1. The graphene intelligent heating mattress is characterized by comprising a mattress body, at least one group of heating sensing modules and a control box, wherein the heating sensing modules are packaged in the mattress body and are connected with the control box;

every group sensing module that generates heat includes that main graphite alkene generates heat area, temperature sensor, at least a slice pair graphite alkene generate heat and take and at least one temperature detect switch, main graphite alkene generate heat take with vice graphite alkene generate heat take each other parallelly connected just main graphite alkene generate heat area, vice graphite alkene generate heat area, temperature sensor and temperature detect switch respectively with the control box is connected, temperature sensor locates on the main graphite alkene generates heat takes, temperature detect switch with vice graphite alkene generate heat take one-to-one just temperature detect switch locates on the vice graphite alkene generate heat of correspondence and takes.

2. The graphene intelligent heating mattress according to claim 1, further comprising a flame retardant pad encapsulated in the mattress body, wherein the flame retardant pad comprises an upper flame retardant layer and a lower flame retardant layer, and the heating sensing module is embedded between the upper flame retardant layer and the lower flame retardant layer.

3. The graphene intelligent heating mattress according to claim 1, wherein the main graphene heating strips and the auxiliary graphene heating strips are sequentially arranged along the length direction of the mattress body.

4. The graphene intelligent heating mattress according to claim 1, wherein the graphene intelligent heating mattress comprises two groups of heating sensing modules arranged side by side along the width direction of the mattress body.

5. The graphene intelligent heating mattress according to claim 1, wherein the distance between the main graphene heating strips and between the auxiliary graphene heating strips in different groups of heating and sensing modules is 5-15cm, and the distance between the adjacent main graphene heating strips and/or the auxiliary graphene heating strips in the same group of heating and sensing modules is 20-25 cm.

6. The graphene intelligent heating mattress according to claim 1, wherein the temperature sensor is connected with the control box through a signal line, and the main graphene heating belt, the auxiliary graphene heating belt and the temperature control switch are respectively connected with the control box through power lines.

7. The graphene intelligent heating mattress according to claim 1, further comprising a power adapter, wherein the control box is connected to an external power supply through the power adapter.

8. The graphene intelligent heating mattress according to claim 7, wherein the control box is connected with the power adapter through a connector, and a nut for fixing is arranged on the connector.

9. The graphene intelligent heating mattress according to claim 1, wherein the heating sensing module is connected with the control box through a USB interface.

10. A graphene intelligent heating system is characterized by comprising a control device and the graphene intelligent heating mattress according to any one of claims 1 to 9, wherein the control device is in communication with the graphene intelligent heating mattress in a wireless mode.

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