CN213395522U - Mirror capable of heating - Google Patents

Abstract

The utility model provides a can heating mirror, includes picture frame, mirror glass, in mirror glass was fixed in the picture frame, the back of mirror glass scribbled the graphite alkene ink layer that can generate heat after the circular telegram, graphite alkene ink layer is connected with the power through temperature controller through the wire, be formed with the cavity that the air flows in the picture frame between the picture frame bottom surface that glass back and glass back of the body are opposite, it has the venthole to distribute on the picture frame back that lies in cavity upper portion, it has the inlet port to distribute on the picture frame back that lies in the cavity lower part. The invention has the advantages that: the air heating efficiency is high, the heating effect is good, the heated air returns to the room from the cavity, and new cold air enters the cavity from the air inlet hole, so that the circulating flow of the indoor air is realized, the indoor air is heated, and the purpose of indoor heating is achieved; the heating structure of the mirror is positioned on the back of the mirror surface, so that the original function of the mirror is not influenced.

Description

Mirror capable of heating

Technical Field

The utility model relates to a mirror preparation technical field especially indicates a mirror that can heat.

Background

The existing Chinese patent application with the application number of CN201510286697.8 named as heatable mirror discloses a heatable mirror, and a resistance wire of a heating device is arranged on the back surface of the mirror. The use problem of the mirror in winter is solved. But the disadvantage is that the resistance wire of the mirror is not uniformly heated, the energy consumption is high, and the mirror has the main function of preventing the mirror from fogging in winter and is difficult to heat the indoor temperature, so the structure of the mirror is still to be improved.

Disclosure of Invention

The utility model aims to solve the technical problem that a mirror that design structure is ingenious, can be indoor heating is provided to above-mentioned prior art current situation.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: this ability heating's mirror, including picture frame, the mirror glass that can the projection formation of image, mirror glass is fixed in the picture frame, its characterized in that: the back of the mirror glass is coated with a graphene ink layer which can generate heat after being electrified, the graphene ink layer is connected with a power supply through a lead by a temperature controller, a cavity with air flowing is formed in the mirror frame between the back of the glass and the bottom surface of the mirror frame opposite to the back of the glass, air outlet holes with upward flowing hot air in the cavity are distributed on the back of the mirror frame positioned at the upper part of the cavity, and air inlet holes with the capability of allowing external automatic air to enter the cavity are distributed on the back of the mirror frame positioned at the lower part of the cavity.

As an improvement, a temperature sensor can be preferably arranged on the graphene ink layer, a transformer for transforming 220V alternating current into 5V-36V is arranged in the temperature controller, when the temperature of the graphene ink layer is higher than 28 ℃, the temperature sensor sends a signal to a program control circuit in the temperature controller, the program control circuit sends a command to a line switch connected to a lead after receiving the signal, the line switch automatically cuts off a power supply after receiving the command, the graphene ink layer is powered off and stops heating, when the temperature of the graphene ink layer is lower than 22 ℃, the temperature sensor also sends a signal to the program control circuit in the temperature controller, the program control circuit sends a command to the graphene ink layer through the line switch after receiving the signal, and the line switch turns on the power supply after receiving the command to enable the graphene ink layer to be heated.

As the improvement, the venthole can be preferably distributed on the picture frame back near the picture frame top position, and the aperture of venthole is 3 ~ 8 mm.

The improved glasses frame is further improved, the air inlet holes can be preferably distributed on the back face of the glass frame close to the bottom of the glass frame, and the aperture of the air inlet holes is 3-8 mm.

As an improvement, vertical grooves can be preferably and respectively arranged on two sides of an imaging surface of the mirror glass, LED luminous bodies are respectively embedded in the grooves and are respectively connected with a power supply through wires.

The LED lamp is characterized in that the groove can be a vertical rectangular strip-shaped groove, and the LED luminous body arranged in the strip-shaped groove is a rectangular lamp tube with the shape matched with the strip-shaped groove.

In a further improvement, the shape of the LED luminous body can be preferably matched with that of the groove, and the back surface of the LED luminous body is flush with the imaging surface of the mirror glass.

In a further improvement, an LED light switch and a graphene ink layer switch can be preferably arranged on the top surface or the bottom surface or the side surface of the mirror frame.

In a further refinement, the imaging side of the mirror glass may preferably be a silver-coated side.

As a further improvement, an explosion-proof film capable of resisting the temperature of 600 ℃ is attached to the surface of the graphene ink layer on the back surface of the mirror glass. The explosion-proof membrane can not only prevent the mirror glass from bursting to hurt human body, but also prevent fragments of the mirror glass from diffusing when the mirror glass is collided or dropped in an unexpected condition, thereby ensuring more sanitary and safer use.

Compared with the prior art, the utility model has the advantages that, firstly, this mirror generates heat and heats mirror glass through graphite alkene ink layer circular telegram, and the air in the picture frame cavity has been heated again together with the mirror glass after heating when graphite alkene ink layer heats mirror glass, because the characteristic that the hot-air flows upwards, the air after the heating flows out and gets into the indoor room of arranging the mirror from the venthole on picture frame back upper portion, and cold air gets into in the picture frame cavity from the inlet hole on picture frame back lower part simultaneously, form the recirculation heating process that hot air goes out, cold air advances, reached the purpose of heating to the room well promptly; yet another important feature is: the adoption of the graphene for heating can not only replace an air conditioner to reduce the use cost, but also has the greater advantages that the graphene heats the mirror glass and the temperature in the glass chamber with the mirror through far infrared rays, and the far infrared rays have the following ten advantages scientifically proved,

first, far infrared can improve blood circulation, because far infrared can go deep into human subcutaneous tissue, so utilize far infrared reaction, make subcutaneous deep skin temperature rise, expand the capillary, promote blood circulation, reviving ferment, strengthen blood and cell tissue metabolism, to cell recovery young very big help and can improve anemia. Regulating blood pressure: hypertension and arteriosclerosis are generally caused by constriction and stenosis of small arteries such as the nervous system, the endocrine system, and the kidneys. Far infrared rays expand microvessels, promote blood circulation to lower hypertension, and improve hypotension symptoms.

Secondly, the far infrared ray can improve the arthralgia, the far infrared ray deep penetration force can reach the deep part of the muscle and the joint, so that the body is warm, the muscle is relaxed, the oxygen and nutrient exchange of a capillary network is driven, and the effects of eliminating fatigue substances, lactic acid and other aging wastes accumulated in the body, eliminating the internal swelling and relieving the ache are excellent.

And the far infrared ray can regulate autonomic nerves, the autonomic nerves mainly regulate visceral functions, and the autonomic nervous system is continuously tense in an anxiety state of a human body for a long time, so that the immunity is reduced, the headache, the dizziness, the insomnia and the weakness are caused, and the limbs are cold. The far infrared ray can adjust the autonomic nerve to keep the best state, and the symptoms can be improved or removed.

And the far infrared rays can protect skin and beautify the face, and the far infrared rays irradiate the human body to generate resonance absorption, so that substances causing fatigue and aging, such as lactic acid, free fatty acid, cholesterol, redundant subcutaneous fat and the like, can be directly metabolized from the skin without passing through the kidney due to the activation of the hair follicle opening and the subcutaneous fat. Therefore, the skin can be smooth and tender. The physical therapy effect of the far infrared ray can improve the heat energy in the body and activate cells, thereby promoting the metabolism of adipose tissues, burning and decomposing, consuming the redundant fat and further effectively losing weight.

And the far infrared ray can improve a circulatory system, the comprehensiveness and the deep penetration of the far infrared ray irradiation, and the far infrared ray physiotherapy device is the only physiotherapy mode which can completely take care of a microcirculation tissue system which is distributed inside and outside the whole body and has no counted number. After the microcirculation is smooth, the systolic pressure is reduced, the oxygen and nutrient supply is sufficient, and the body is naturally light and healthy. Strengthening the liver function: the liver is the largest chemical plant in the body and is the purifier of blood. The deep effect of in vivo heat caused by far infrared ray irradiation can activate cells, improve tissue regeneration capability, promote cell growth, strengthen liver function, improve liver detoxification and toxin expelling effects, keep the internal organ environment in a good state, and be the best disease prevention strategy.

Sixthly, the activity of the biological molecules is activated, and particularly, the photon energy (1.6-0.001 electron volt) in the infrared region can not activate the electronic energy level of the molecules, so that the substances can not be ionized like ultraviolet rays, and the infrared radiation can only activate the vibration energy level of the molecules. The energy difference between the vibration energy levels is generally 1 electron volt or less. That is, since the atomic bond energy of the far infrared energy forming molecule is small, the molecular structure cannot be changed. Nevertheless, under the action of far infrared photons, especially 2-6 micron far infrared photons, the molecular energy level of the organism is excited to be at a higher vibration energy level, which activates the activity of biomacromolecules such as nucleic acid protein and the like, thereby exerting the function of regulating activities such as organism metabolism, immunity and the like by the biomacromolecules, being beneficial to the recovery and balance of organism functions and achieving the purposes of preventing and treating diseases.

Seventh, it can enhance metabolism, if the metabolism of human body is disordered, and the exchange of internal and external substances is abnormal, then various diseases will not be affected. Disorders such as water electrolyte metabolism, which are serious life threatening; diabetes mellitus due to disturbances of sugar metabolism; disorders of lipid metabolism cause cardiovascular disease, obesity; gout caused by protein metabolism disorder, etc. By the heat effect of far infrared, the vitality of cells can be increased, the mechanism of nerve body fluid is adjusted, metabolism is enhanced, and the matter exchange in the body is in a stable state.

And eighth, the immune function is improved, and the immunity is a physiological protection reaction of a human body, comprises cellular immunity and humoral immunity, and has an extremely important effect on resisting diseases of the human body. Clinical observation shows that the far infrared ray can improve the phagocytic function of macrophage, regulate the cellular immunity and humoral immunity of human body and is favorable to human health.

Ninth, the mechanism of the anti-inflammatory action is as follows: a) the far infrared heat action eliminates the pathological process of inflammation through the response reaction of nerve body fluid, accelerates the original destroyed physiological equilibrium state to restore to normal, improves the disease resistance of local and whole bodies, activates the function of immunocyte, strengthens the phagocytic function of leucocyte and reticular skin cell, and achieves the aim of diminishing inflammation and inhibiting bacteria. b) The infrared heat effect increases the skin temperature, reduces the sympathetic nerve sensing ability, releases vasoactive substances, expands blood vessels, accelerates blood flow, improves blood circulation, enhances tissue nutrition, activates tissue metabolism, improves oxygen supply of cells, improves the blood and oxygen supply states of a focus area, enhances the regeneration ability of the cells, controls the development and localization of inflammation, and accelerates the repair of the focus. c) The far infrared heat effect improves microcirculation, establishes collateral circulation, enhances the stability of cell membrane, regulates the concentration of ions, improves osmotic pressure, accelerates the discharge of toxic substance metabolites, accelerates the absorption of exudates, and leads to the regression of inflammatory edema.

Tenthly, analgesia and infrared heat effect, and the excitability of nerve endings is reduced; improving blood circulation, eliminating edema, and relieving chemical and mechanical irritation of nerve terminal; the far infrared heat action improves the pain threshold, and the pain relieving function is realized by the far infrared heat action. The biological effect of far infrared ray, in addition to the above mentioned thermal effect, has many other important biological effects, such as the relationship between far infrared ray and life, the improvement of microcirculation by infrared ray, the activation of water molecules, the activation of tissue cells, and other important functions.

Therefore, the utility model discloses a graphite alkene heats the mirror, not only makes the mirror can not go up the fog, has brought unprecedented benefit for indoor personnel moreover, especially improves now living standard day by day, and people pay more attention to the maintenance of health, adjusts the room temperature through graphite alkene, has filled a domestic blank, is the innovation of an exploitation promptly.

Secondly, the graphene ink layer can control and adjust the temperature of the graphene ink layer through a temperature controller, the range of the temperature in the heated air can be adjusted, the indoor temperature is kept in a set constant temperature range of 18-28 ℃, and not only can indoor personnel feel comfortable, but also when the graphene ink layer heats the air, moisture in the air cannot be pumped out, namely, the moisture in the air cannot be lost during heating, the situation that the indoor air is dry due to the loss of moisture during heating of a similar air conditioner is avoided, indoor people feel more comfortable and safer, namely, the heating effect is better; thirdly, the left side and the right side of the mirror glass can be embedded with LED luminescent lamps, so that the mirror can shine more clearly and clearly without dazzling when looking into the mirror, and the brightness of the indoor environment can be increased; the mirror can be conveniently hung and fixed on a wall body, the occupied space is small, the installation is convenient, the appearance is attractive, and therefore the indoor environment is further beautified.

Drawings

Fig. 1 is a perspective view of an embodiment of the present invention;

FIG. 2 is an exploded view of the structure of FIG. 1;

FIG. 3 is a front perspective view of FIG. 1 with the wall removed;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 3;

FIG. 6 is an exploded view of the structure of FIG. 3;

FIG. 7 is a further exploded view of the structure of FIG. 6;

FIG. 8 is a further exploded view of FIG. 7;

FIG. 9 is an exploded view of the mirror glass of FIG. 8;

fig. 10 is an enlarged view of a portion I in fig. 4.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

As shown in fig. 1 to 10, the mirror capable of heating of the present embodiment includes a mirror frame 1 and mirror glass 2 capable of projecting and imaging, the mirror glass 2 is fixed in the mirror frame 1, a graphene ink layer 3 capable of heating after being electrified is coated on the back surface of the mirror glass 2, and the specific structure of the graphene ink layer 3 belongs to the prior art, and therefore, detailed description is not given. The graphene ink layer 3 is connected with a power supply through a temperature controller by a lead, a cavity 11 for air flowing is formed in the mirror frame 1 between the back of the glass and the bottom surface of the mirror frame opposite to the back of the glass, air outlet holes 41 for upward flowing of hot air in the cavity 11 are distributed on the back of the mirror frame positioned at the upper part of the cavity, and air inlet holes 42 for enabling external automatic air to enter the cavity 11 are distributed on the back of the mirror frame positioned at the lower part of the cavity. The picture frame back is provided with the back opening, aluminum alloy plate 4 has been put to the lid of can shirking on the back opening, venthole 41 and inlet port 42 set up respectively on aluminum alloy plate 4, graphite alkene ink layer 3 can be worn out from venthole 41 or inlet port 42 with the connecting wire of power, also can wear out from the installation gap of aluminum alloy plate 4 with picture frame 1, can also set up the aperture on the lateral wall of picture frame 1 and wear out from the aperture, also can install the response charger on graphite alkene ink layer 3 of course, realize wireless electrically conducting. The specific circuit structure of the temperature controller belongs to the prior art, and therefore, the detailed description is not provided. The air in the outside is colder, and colder air gets into cavity 11 from inlet port 42, and graphite alkene ink layer 3 heats the air in the heating cavity 11 inner chamber, because hot-air rises automatically, and consequently the hot-air after being heated leaves picture frame 1 from venthole 41 and enters into the outside to realize indoor air's circulation flow and heating, reach the purpose that improves indoor temperature and carry out the heating.

The temperature control device is characterized in that a temperature sensor is arranged on the graphene ink layer 3, a transformer for transforming 220V alternating current into 5V-36V is arranged in the temperature controller, when the temperature of the graphene ink layer 3 is higher than 28 ℃, the temperature sensor sends a signal to a program control circuit in the temperature controller, the program control circuit sends an instruction to a line switch connected to a wire after receiving the signal, the line switch automatically cuts off a power supply after receiving the instruction, the graphene ink layer 3 is powered off and stops heating, when the temperature of the graphene ink layer 3 is lower than 22 ℃, the temperature sensor also sends a signal to the program control circuit in the temperature controller, the program control circuit sends an instruction to the line switch after receiving the signal, and the line switch turns on the power supply after receiving the instruction to enable the graphene ink layer 3 to be powered on and heat. The venthole 41 distributes on the picture frame back that is close to picture frame top position, and the aperture of venthole 41 is 3 ~ 8 mm. The air inlet 42 distributes on the picture frame back that is close to the picture frame bottom position, and the aperture of air inlet 42 is 3 ~ 8 mm. The specific structure of the temperature sensor is well known in the art and will not be described in detail.

Vertical grooves 21 are respectively formed in two sides of an imaging surface 20 of the mirror glass 2, LED luminous bodies 22 are respectively embedded in the grooves 21, and the LED luminous bodies 22 are respectively connected with a power supply through conducting wires. The groove 21 is a vertical rectangular strip-shaped groove, and the LED luminous body 22 arranged in the strip-shaped groove is a rectangular lamp tube with the shape matched with the strip-shaped groove. The shape of the LED emitter 22 is adapted to the shape of the recess 21, and the back surface of the LED emitter 22 is flush with the imaging surface 20 of the mirror glass 2. The LED light switch 23 and the graphene ink layer switch 31 are provided on the top surface, the bottom surface, or the side surface of the lens frame 1. The image plane 20 of the mirror glass 2 is a silver-coated plane. The mirror frame on the back of the heating mirror is provided with a fixing clamping part 12 or a hanging part which can be conveniently arranged on the wall surface 5 or other fixing surfaces. The specific structure of the rectangular lamp tube belongs to the known technology, and therefore, the detailed description is not provided. The lead of the LED illuminator 22 is different from the lead of the graphene ink layer 3, so that the LED illuminator 22 and the graphene ink layer 3 are in different circuit loops, and the operation of another circuit is not affected by the open circuit or short circuit of any circuit. An explosion-proof film (not shown in the figure) capable of resisting the temperature of 600 ℃ is further attached to the surface of the graphene ink layer on the back surface of the mirror glass 2. Thereby greatly improving the safety performance of use.

The working principle is as follows: graphite alkene ink layer can heat cavity internal air, and cold air gets into the cavity from the inlet port, is heated the back in the cavity and leaves the picture frame from the venthole, therefore the indoor air can last get into the cavity and heated, realizes indoor air current circulation, and the heated air improves indoor temperature gradually, reaches the purpose to indoor heating.

Claims (10)

1. A mirror that can heat, includes picture frame (1), mirror glass (2) that can the projection formation of image, in mirror frame (1) is fixed in mirror glass (2), its characterized in that: the back of mirror glass (2) scribbles graphite alkene ink layer (3) that can generate heat after the circular telegram, graphite alkene ink layer (3) are connected with the power through temperature controller through the wire, are formed with air flow's cavity (11) in picture frame (1) between the picture frame bottom surface that glass back and glass back are opposite, and the hot-air that is located cavity upper portion distributes on the picture frame back that has the cavity (11) and upwards flows venthole (41), distributes on the picture frame back that is located the cavity lower part and has external automatic air inlet (42) that can enter into in cavity (11).

2. The heatable mirror as defined in claim 1, wherein: the temperature control device is characterized in that a temperature sensor is arranged on the graphene ink layer (3), a transformer for transforming 220V alternating current into 5V-36V is arranged in the temperature controller, when the temperature of the graphene ink layer (3) is higher than 28 ℃, the temperature sensor sends a signal to a program control circuit in the temperature controller, the program control circuit sends an instruction to a line switch connected to a lead after receiving the signal, the line switch automatically cuts off a power supply after receiving the instruction, the graphene ink layer (3) is powered off and stops heating, when the temperature of the graphene ink layer (3) is lower than 22 ℃, the temperature sensor also sends a signal to the program control circuit in the temperature controller, the program control circuit sends an instruction to the line switch after receiving the signal, and the line switch turns on the power supply after receiving the instruction to enable the graphene ink layer (3) to be powered on and heat.

3. The heatable mirror as defined in claim 1, wherein: the ventholes (41) are distributed on the back face of the mirror frame close to the top of the mirror frame, and the aperture of the ventholes (41) is 3-8 mm.

4. A heatable mirror as claimed in claim 3, wherein: the air inlet holes (42) are distributed on the back face of the picture frame close to the bottom of the picture frame, and the aperture of the air inlet holes (42) is 3-8 mm.

5. A heatable mirror as claimed in any one of claims 1 to 4, characterised in that: vertical grooves (21) are respectively formed in two sides of an imaging surface (20) of the mirror glass (2), LED luminous bodies (22) are respectively embedded in the grooves (21), and the LED luminous bodies (22) are respectively connected with a power supply through conducting wires.

6. The heatable mirror as defined in claim 5, wherein: the groove (21) is a vertical rectangular strip-shaped groove, and the LED luminous body (22) arranged in the strip-shaped groove is a rectangular lamp tube with the shape matched with the strip-shaped groove.

7. The heatable mirror as defined in claim 6, wherein: the shape of the LED luminous body (22) is matched with that of the groove (21), and the back surface of the LED luminous body (22) is flush with the imaging surface (20) of the mirror glass (2).

8. The heatable mirror as defined in claim 6, wherein: an LED luminous body switch (23) and a graphene ink layer switch (31) are arranged on the top surface, the bottom surface or the side surface of the mirror frame (1).

9. The heatable mirror as defined in claim 5, wherein: the imaging surface (20) of the mirror glass (2) is a silver-coated surface.

10. A heatable mirror as claimed in any one of claims 1 to 4, characterised in that: and an explosion-proof film capable of resisting the temperature of 600 ℃ is pasted on the surface of the graphene ink layer on the back surface of the mirror glass (2).

Images