CN220069239U - High-temperature-resistant backrest for beauty - Google Patents

Abstract

The utility model discloses a high-temperature-resistant beauty backrest, relates to the technical field of archaize building structures, and aims to solve the problems that when the surface temperature of the beauty backrest is high, the heat dissipation efficiency is low and the effect is relatively common when the beauty backrest dissipates heat in a water cooling mode. The key points of the technical scheme are as follows: the high-temperature-resistant beauty backrest comprises a railing, a backrest rod and a bench, wherein the bottom surface of the railing is fixedly connected with a plurality of first heat transfer elements and second heat transfer elements, the other ends of the first heat transfer elements and the second heat transfer elements are fixedly connected to the outer peripheral wall of the backrest rod, the railing and the backrest rod are used for transferring heat to the first heat transfer elements and the second heat transfer elements, the lower end of the outer peripheral wall of the backrest rod is fixedly connected with a third heat transfer element, the other ends of the third heat transfer elements are fixedly connected to the bench, the backrest rod and the bench are used for transferring heat to the third heat transfer elements, and the heat absorbed by the first heat transfer elements, the second heat transfer elements and the third heat transfer elements is in contact with water. The temperature of the surface of the beauty rest is further absorbed by the first heat transfer element, the second heat transfer element and the third heat transfer element and then discharged by water flow, so that the water cooling and heat dissipation effects are further improved.

Description

High-temperature-resistant backrest for beauty

Technical Field

The utility model relates to the technical field of archaize building structures, in particular to a high-temperature-resistant beauty backrest.

Background

The "chair for beauty" is also called "fly chair" or "Wu Wangkao" and is named "gooseneck chair", which is a wooden building with bench at the bottom and fence at the top, and the outward-extending backrest is bent like a gooseneck. The elegant and subtle curve design of the chair conforms to the outline of a human body, and the chair is quite comfortable to sit on. The novel back-image display device is usually built on the water facing side of a corridor or pavilion surrounding sill, and has the fun of wave reflection besides rest.

The beauty rest is also a railing, is the deformation and the derivative of the railing, particularly, the place needing to be provided with the railing is the railing, the simplest mode is to be made into the railing, the beauty and functional corridor stool can be made without trouble, and the rest is added on the basis of the corridor stool, so that the beauty rest is formed.

In the prior art, when the American lean against the sunshine and is irradiated for a long time, the surface temperature of the American lean against is higher, and the heat dissipation effect can be further improved when the American lean against is dissipated in a mode of cooling the American lean against the hollow structure to cool the inside.

Thus, the high-resistance Wen Meiren is proposed to solve the above-mentioned problems.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide a high-resistance Wen Meiren backrest, and solve the problem that the radiating effect can be further improved when a beauty radiates heat by a water cooling mode.

The technical aim of the utility model is realized by the following technical scheme: the high-temperature-resistant beauty backrest comprises a railing, a leaning rod and a bench, wherein the bottom surface of the railing is fixedly connected with a plurality of first heat transfer elements and second heat transfer elements, the other ends of the first heat transfer elements and the second heat transfer elements are fixedly connected to the outer peripheral wall of the leaning rod, the railing and the leaning rod transfer heat to the first heat transfer elements and the second heat transfer elements, the lower end of the outer peripheral wall of the leaning rod is fixedly connected with a third heat transfer element, the other ends of the third heat transfer elements are fixedly connected to the bench, the leaning rod and the bench transfer heat to the third heat transfer elements, and the heat absorbed by the first heat transfer elements, the second heat transfer elements and the third heat transfer elements is in contact with water.

Through adopting above-mentioned technical scheme, heat transfer element one, heat transfer element two and railing, lean on the pole to connect the contact, heat transfer element three and railing, lean on the pole to connect the contact, railing and lean on the heat transfer element one and heat transfer element two on, lean on the heat transfer element three on the heat transfer element of pole and bench, heat transfer element one, heat transfer element two and heat transfer element three pass through with water contact, take away the heat absorbed through rivers, further with railing, lean on the heat absorption on pole and the bench and discharge again, on water cooling radiating basis, radiating efficiency and effect have been improved.

The utility model is further provided with: the specific heat capacity of the first heat transfer element, the second heat transfer element and the third heat transfer element is higher than that of the railing, the leaning rod and the bench.

By adopting the technical scheme, the heat of the surface of the low-specific-heat-capacity object can be transferred to the surface of the high-specific-heat-capacity object, so that the heat of the railing and the leaning rod is transferred to the first heat transfer element and the second heat transfer element, and the heat of the leaning rod and the bench is transferred to the third heat transfer element.

The utility model is further provided with: the first heat transfer element, the second heat transfer element, the third heat transfer element, the railing, the leaning rod and the bench are hollow structures and are mutually communicated.

By adopting the technical scheme, water flow can flow into the interiors of the first heat transfer element, the second heat transfer element, the third heat transfer element, the railing, the leaning rod and the bench and circulate inside each other, so that heat can be taken away by the water flow to achieve the heat dissipation effect.

The utility model is further provided with: the bottom surface of the inner peripheral wall of the railing is provided with a first through hole and a second through hole, the top end of the first heat transfer element is communicated with the first through hole, the top end of the second heat transfer element is communicated with the second through hole, the top surface of the inner peripheral wall of the bench is provided with a third through hole, the bottom end of the third heat transfer element is communicated with the third through hole, and water flows into the first through hole and the first through hole, flows into the second through hole and flows out of the third through hole.

By adopting the technical scheme, the first through hole and the second through hole enable water flow entering the railing to flow downwards into the first heat transfer element, the second heat transfer element and the third heat transfer element, and absorbed heat flows through the third through hole and finally flows into the bench.

The utility model is further provided with: the first heat transfer element and the second heat transfer element are obliquely arranged downwards and form an inverted triangle structure.

By adopting the technical scheme, the inverted triangle structure enables the first heat transfer element and the second heat transfer element to have good structural stability and bearing capacity.

The utility model is further provided with: the first heat transfer element comprises a first support plate, a first support frame and a first guard plate, wherein the first support plate is fixedly connected with one side of the bottom surface of the railing, one end of the first support frame is fixedly connected with one end of the first support plate, the other end of the first support frame is fixedly connected with the peripheral wall of the railing, and the first guard plate is fixedly connected with one side, close to the side wall of the railing, of the first support plate.

Through adopting above-mentioned technical scheme, heat transfer element one has increased the area of contact of heat transfer element one with the railing through backup pad one, has reduced the pressure that bears on the unit area, and backup pad one fixed connection's backplate one makes the railing more stably fix on heat transfer element one simultaneously, has strengthened the supporting effect.

The utility model is further provided with: the second heat transfer part comprises a second support plate, a second support frame and a second guard plate, wherein the second support plate is fixedly connected with one side of the bottom surface of the railing, one end of the second support frame is fixedly connected with one end of the second support plate, the other end of the second support frame is fixedly connected with the peripheral wall of the railing, and the second guard plate is fixedly connected with one side, close to the side wall of the railing, of the second support plate.

Through adopting above-mentioned technical scheme, the heat transfer element two has increased the area of contact of heat transfer element two with the railing through backup pad two, has reduced the pressure that bears on the unit area, and backup pad two fixed connection's backplate makes railing more stably fix on heat transfer element two simultaneously, has strengthened the supporting effect.

The utility model is further provided with: the heat transfer element III comprises a clamping block and a supporting frame III, a U-shaped through groove is formed in the clamping block, the clamping block is fixedly connected to the outer peripheral wall of the leaning rod, the inner peripheral wall of the through groove of the clamping block is attached to the outer peripheral wall of the leaning rod, and the top end of the supporting frame III is integrally formed with the clamping block, and the bottom end of the supporting frame III is fixedly connected with the top surface of the bench.

Through adopting above-mentioned technical scheme, the heat transfer element three passes through the U-shaped through groove inner peripheral wall of fixture block and leans on the closely laminating of pole periphery wall, and support frame three bottom and bench top surface fixed connection support fixedly, make the heat transfer element three can be stable will lean on the pole to support fixedly on the bench.

The utility model is further provided with: the railing, the leaning rod and the bench are made of aluminum alloy materials, and the first heat transfer element, the second heat transfer element and the third heat transfer element are made of stainless steel materials.

By adopting the technical scheme, the specific heat capacity of the first heat transfer element, the second heat transfer element and the third heat transfer element is higher than that of the railing, the leaning rod and the bench, and the stainless steel material is easier to dissipate heat.

In summary, the utility model has the following beneficial effects: the railing, lean against pole and bench are hollow structure and communicate with each other with hollow heat transfer element one, heat transfer element two and heat transfer element three of structure, heat transfer element one and heat transfer element two's one end fixed connection is on the bottom surface of railing, and the other end fixed connection is on leaning against the peripheral wall of pole, the rivers are leaned against on the interior flow of beauty after letting in water, first inflow railing, and then follow through opening one and opening two and flow down through heat transfer element one, heat transfer element two and heat transfer element three's specific heat capacity is higher than railing, lean against pole and bench, and absorb the heat of railing, lean against pole and bench, the heat absorbed is taken away by the rivers that flow through again, finally flow into bench through the opening and discharge from the delivery port, heat transfer element one and heat transfer element two can be fixed on leaning against the pole with the steady support of railing, heat transfer element three will lean against the pole steady support and fix on the bench, when guaranteeing to add water heat dissipation, make and lean against the pole can not appear, and realize water-cooling circulation simultaneously, can further improve people's water cooling efficiency and lean against the railing.

Drawings

FIG. 1 is a schematic diagram of a first embodiment of the present utility model;

FIG. 2 is a schematic diagram of a second embodiment of the present utility model;

FIG. 3 is a schematic cross-sectional view of the present utility model;

FIG. 4 is a schematic view of a first heat transfer element according to the present utility model;

FIG. 5 is a schematic view of a second heat transfer element according to the present utility model;

fig. 6 is a schematic structural view of a third heat transfer member in the present utility model.

In the figure:

11. railing; 12. a leaning rod; 13. a bench; 14. a first supporting plate; 15. a first guard board; 16. a first supporting frame; 17. a second supporting plate; 18. a second guard board; 19. a second supporting frame; 20. a clamping block; 21. and a third supporting frame.

Detailed Description

The present utility model will be described in detail below with reference to the accompanying drawings and examples.

Examples:

as shown in fig. 1 to 3, the high temperature resistant beauty rest comprises a first heat transfer element, a second heat transfer element, a third heat transfer element, a railing 11, a rest bar 12 and a bench 13 which are hollow and are communicated with each other, wherein the top ends of the first heat transfer element and the second heat transfer element are welded on the bottom surface of the railing 11, the other end of the first heat transfer element is welded on the rest bar 12, one end of the third heat transfer element is welded on the peripheral wall of the rest bar 12, the other end of the third heat transfer element is welded on the top surface of the bench 13, when the water cooling is carried out on the inside of the beauty, water flows into the railing 11 firstly, then flows into the first heat transfer element and the second heat transfer element which are communicated with the first heat transfer element through a through opening and a through opening formed on the bottom surface of the inner peripheral wall of the railing 11, the heat on the railing 11 and the leaning rod 12 is absorbed, the water flowing downwards from the railing 11 is taken away and flows into the leaning rod 12 continuously, the heat transfer element III absorbs the heat on the leaning rod 12 and the leaning rod 13, the absorbed heat is taken away through the water flowing in the leaning rod 12, the water flows into the stool 13 continuously through the through hole, finally the water flowing into the stool 13 dissipates heat to the stool 13 and is discharged through the through hole and the water outlet, after the beauty leans on the inside to pass water, the heat transfer element I, the heat transfer element II and the heat transfer element III can also effectively support the fixed railing 11 and the leaning rod 12, so that the railing 11 and the leaning rod 12 can not collapse, the efficiency and the effect of water cooling by the beauty can be further improved while the water cooling circulation heat dissipation is realized.

As shown in fig. 3 to 4, the first heat transfer element is made of 2024 aluminum alloy material and is of a hollow structure, the specific heat capacity of the first heat transfer element is higher than that of 7075 aluminum alloy material, the first support frame 16 in the first heat transfer element is of a strip-shaped columnar structure and is arranged obliquely downwards, the top end of the first heat transfer element and the first support frame 14 are integrally formed, the bottom end of the first support frame is welded on the peripheral wall of the leaning rod 12, the connection part of the first support frame 16 and the leaning rod 12 is communicated, the first support frame 14 in the first heat transfer element is welded on the bottom surface of the railing 11, the cross section of the first support frame is in a cross shape, the top surface of the first support frame 14 is attached to the bottom surface of the railing 11, a square through hole is formed in the top surface of the first support frame 14 and is communicated with the through hole formed in the bottom surface of the railing 11, one surface of the first support frame 14, which is close to the side wall of the railing 11, and the first guard plate 15 extends upwards and is welded on the side wall of the railing 11.

The heat transfer element I is hollow, so that water flows into the heat transfer element I, the specific heat capacity of the heat transfer element I is higher than that of the railing 11 and the leaning rod 12, when the railing 11 and the leaning rod 12 are in contact with the heat transfer element I, heat on the railing 11 and the leaning rod 12 can be absorbed by the heat transfer element I, the absorbed heat is taken away by the water flow, then flows into the leaning rod 12 and downwards continues to flow, meanwhile, the support plate I14 is in a cross shape, the contact area with the railing 11 is increased, the bearing pressure on a unit area is reduced, the guard plate I15 is welded on the side wall of the railing 11, the railing 11 is more stably fixed on the heat transfer element I, the supporting effect is enhanced, and the railing 11 can be effectively supported and fixed on the leaning rod 12 when the heat transfer element I absorbs and dissipates heat.

As shown in fig. 3 and 5, the second heat transfer element is made of 2024 aluminum alloy material and is of a hollow structure, the specific heat capacity of the second heat transfer element is higher than that of 7075 aluminum alloy material, the second support frame 19 in the second heat transfer element is of a strip-shaped columnar structure and is arranged obliquely downwards, the length of the second support frame 19 is shorter than that of the first support frame 16, the cross-sectional area and the volume of the second support frame 19 are smaller than those of the first support frame 16, the top end of the second support frame is integrally formed with the second support frame 17 and the bottom end of the second support frame are welded on the peripheral wall of the leaning rod 12, the welding surface is two surfaces adjacent to the welding surface of the first heat transfer element, the second heat transfer element is symmetrically arranged on the two welding surfaces, the joint of the second support frame 19 and the leaning rod 12 is communicated, the second support plate 17 in the second heat transfer element is welded on the bottom surface of the railing 11, the cross-shaped support plate 17 is smaller than the first support plate 14, the top surface of the second support plate 17 is attached to the bottom surface of the railing 11, square through openings are formed in the top surface of the second support plate 17, the square through openings are communicated with the second through openings formed in the bottom surface of the railing 11, one surface of the second support plate 17 is integrally formed with the second protection plate 18, the cross-plate 18 is smaller than the cross-sectional area of the first protection plate 15 and the second protection plate 18 is welded on the side upper side of the railing 11.

The hollow design of the second heat transfer element can enable water flow to flow into the second heat transfer element, the specific heat capacity of the second heat transfer element is higher than that of the railing 11 and the leaning rod 12, when the railing 11 and the leaning rod 12 are in contact with the heat transfer element, heat on the railing 11 and the leaning rod 12 can be absorbed by the second heat transfer element, the water flow continuously flows into the leaning rod 12 and downwards continues to flow after absorbing the heat, meanwhile, the second support plate 17 is in a cross shape, the contact area with the railing 11 is increased, the bearing pressure on the unit area is reduced, meanwhile, the second protection plate 18 is welded on the side wall of the railing 11, so that the railing 11 is more stably fixed on the second heat transfer element, the first heat transfer element and the second heat transfer element form an inverted triangle support structure on the leaning rod 12 and the railing 11, the first heat transfer element and the second heat transfer element have excellent structural stability and bearing capacity, and the second heat transfer element are supported in a matched mode while absorbing and radiating heat, and the railing 11 is further supported and fixed on the leaning rod 12.

As shown in fig. 3 and 6, the third heat transfer element is made of 2024 aluminum alloy material and is of a hollow structure, the specific heat capacity of the third heat transfer element is higher than that of 7075 aluminum alloy material, a U-shaped through groove is formed in a clamping block 20 in the third heat transfer element, the clamping block 20 is welded on the outer peripheral wall of the leaning rod 12, the inner peripheral wall of the through groove is completely attached to the outer peripheral wall of the leaning rod 12, meanwhile, a square through hole is formed in the inner peripheral wall of the through groove and is communicated with the leaning rod 12, one end of the clamping block 20 is integrally formed with a third support frame 21, the cross section area of the third support frame is larger than that of the first support frame 16, the third support frame 21 is obliquely arranged downwards, and the bottom end of the third support frame is welded and communicated with the top surface of the bench 13.

The heat transfer element is welded on the outer peripheral wall of the leaning rod 12 through the clamping block 20, the inner peripheral wall of the U-shaped through groove of the clamping block 20 is tightly attached to the outer peripheral wall of the leaning rod 12, the leaning rod 12 can be better limited and fixed, one end of the clamping block 20 is integrally formed with the third support frame 21, the bottom end of the clamping block is welded on the top surface of the bench 13 to support and fix the leaning rod 12, the third heat transfer element can stably support and fix the leaning rod 12 on the bench 13, the clamping block 20 is communicated with the leaning rod 12 to enable water flowing in the leaning rod 12 to flow into the third support frame 21, the specific heat capacity of the third heat transfer element is higher than the specific heat capacity of the leaning rod 12 and the bench 13, heat is absorbed from the leaning rod 12 and the bench 13, the absorbed heat is taken away by the water flowing into the third support frame 21, the absorbed heat is discharged from a water outlet in the bench 13 through the third through hole formed in the bench 13.

The railing 11, lean on pole 12 and bench 13 to be hollow structure and adopt 7075 aluminum alloy material to make, lean on the top welding of pole 12 in the bottom surface of railing 11, lean on the bottom welding of pole 12 in the top of bench 13, carry out water-cooling heat dissipation through external water source, circular inlet opening has been seted up to railing 11 outer wall one side, the inlet tube stretches into in the inlet opening, the water pump draws water from the water tank makes rivers flow into railing 11 from the inlet tube, after rivers are full of railing 11 inside, rivers flow into lean on in pole 12 and the downward flow that communicate with railing 11, simultaneously rivers also can flow into heat transfer part one and heat transfer part two and flow into lean on in the pole 12 again, the rivers in leaning on pole 12 again flows into heat transfer part three and bench 13, finally rivers all flow into and gather in bench 13, circular outlet opening has been seted up to the lateral wall of bench 13, outlet opening communicates with the outlet pipe, rivers through the outlet pipe after the heat absorption are discharged into the water tank again, through the outlet pipe is cooled down, again through the water tank to inlet tube inflow into railing 11, with this reciprocating cycle cooling heat dissipation.

As shown in fig. 1 to 3, when the temperature of the outside water source is higher, the outside water source is communicated with the railing 11 through the water inlet pipe and water is led inwards, the water flow fills the inside of the railing 11 and flows into the first heat transfer element, the second heat transfer element and the leaning rod 12 simultaneously, the first heat transfer element and the second heat transfer element absorb heat of the railing 11 and the leaning rod 12 and absorb the heat through water flowing through the inside and collect the heat into the leaning rod 12 and further flow downwards, the water flow flows downwards from the leaning rod 12 into the third heat transfer element and the bench 13, the heat transfer element absorbs the heat of the leaning rod 12 and the bench 13, the absorbed heat is taken away through the water flow, the water flow finally flows into the bench 13 from the inside of the third heat transfer element and flows into the bench 13 through water outlet holes formed in the outer side wall of the bench 13, the water outlet holes are communicated with a water outlet pipe of the outside water source, the water flow after absorbing the heat is discharged through the water outlet pipe and flows into the water tank, and flows into the railing 11 through the water tank after cooling, the water flows into the railing 11 through the water inlet pipe, and is cooled, the heat is cooled back and circulated repeatedly, the heat dissipation element and the third heat transfer element and the bench 12 are fixed on the heat dissipation base and the heat dissipation base by the railing 11, and the heat dissipation effect is further improved, and the heat dissipation effect is further supported by the heat dissipation base is also achieved, and the heat dissipation effect is further supported by the heat and the heat dissipation base is fixed by the heat and the rest on the people.

The above description is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (9)

1. High temperature resistant beauty leans on, including railing (11), lean on pole (12) and bench (13), its characterized in that: the bottom surface of the railing (11) is fixedly connected with a plurality of first heat transfer elements and second heat transfer elements, the other ends of the first heat transfer elements and the second heat transfer elements are fixedly connected to the peripheral wall of the leaning rod (12), the railing (11) and the leaning rod (12) transfer heat to the first heat transfer elements and the second heat transfer elements, the lower end of the peripheral wall of the leaning rod (12) is fixedly connected with a third heat transfer element, the other ends of the third heat transfer elements are fixedly connected to the bench (13), the leaning rod (12) and the bench (13) transfer heat to the third heat transfer elements, and the heat absorbed by the first heat transfer elements, the second heat transfer elements and the third heat transfer elements is in contact with water.

2. The high temperature resistant beauty backrest of claim 1, wherein: the specific heat capacity of the first heat transfer element, the second heat transfer element and the third heat transfer element is higher than that of the railing (11), the leaning rod (12) and the bench (13).

3. The high temperature resistant beauty backrest of claim 2, wherein: the first heat transfer element, the second heat transfer element, the third heat transfer element, the railing (11), the leaning rod (12) and the bench (13) are hollow structures and are mutually communicated.

4. A high temperature resistant beauty rest according to claim 3, characterized in that: the bottom surface of the inner peripheral wall of the railing (11) is provided with a first through hole and a second through hole, the top end of the first heat transfer element is communicated with the first through hole, the top end of the second heat transfer element is communicated with the second through hole, the top surface of the inner peripheral wall of the bench (13) is provided with a third through hole, the bottom end of the third heat transfer element is communicated with the third through hole, and water flows into the first through hole and the first through hole, flows into the second through hole and flows out of the third through hole.

5. A high temperature resistant beauty rest according to claim 3, characterized in that: the first heat transfer element and the second heat transfer element are obliquely arranged downwards and form an inverted triangle structure.

6. The high temperature resistant beauty backrest of claim 5, wherein: the first heat transfer element comprises a first support plate (14), a first support frame (16) and a first guard plate (15), wherein the first support plate (14) is fixedly connected with one side of the bottom surface of the railing (11), one end of the first support frame (16) is fixedly connected with the bottom end of the support plate, the other end of the first support frame is fixedly connected with the peripheral wall of the railing (11), and the first guard plate (15) is fixedly connected with one side, close to the side wall of the railing (11), of the first support plate (14).

7. The high temperature resistant beauty backrest of claim 5, wherein: the second heat transfer element comprises a second support plate (17), a second support frame (19) and a second guard plate (18), wherein the second support plate (17) is fixedly connected with one side of the bottom surface of the railing (11), one end of the second support frame (19) is fixedly connected with the bottom end of the support plate, the other end of the second support frame is fixedly connected with the peripheral wall of the railing (11), and the second guard plate (18) is fixedly connected with one side, close to the side wall of the railing (11), of the second support plate (17).

8. A high temperature resistant beauty rest according to claim 3, characterized in that: the heat transfer element III further comprises a clamping block (20) and a supporting frame III (21), the clamping block (20) is provided with a U-shaped through groove, the clamping block (20) is fixedly connected to the outer peripheral wall of the leaning rod (12) and the inner peripheral wall of the clamping block is attached to the outer peripheral wall of the leaning rod (12), and the top end of the supporting frame III (21) is integrally formed with the clamping block (20) and the bottom end of the supporting frame III is fixedly connected with the top surface of the bench (13).

9. A high temperature resistant beauty rest according to claim 3, characterized in that: the railing (11), the leaning rod (12) and the bench (13) are made of 7075 aluminum alloy materials, and the first heat transfer element, the second heat transfer element and the third heat transfer element are made of 2024 aluminum alloy materials.