CN111374884A

CN111374884A - Tripod body structure of steam physiotherapy device

Info

Publication number: CN111374884A
Application number: CN201811626248.3A
Authority: CN
Inventors: 陈鸿烈
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-12-28
Filing date: 2018-12-28
Publication date: 2020-07-07

Abstract

The invention provides a tripod body structure of a steam physiotherapy device, which comprises: a basin-shaped base and a cylindrical tripod body with openings at two ends. The tripod body is arranged above the base and spliced into a complete tripod body. The tripod body and the base are made of glass fiber, the middle layer is a cement layer made of cement, and the inner layer is a patch layer. The cement layer of the middle layer and the glass fiber layer of the outer layer are bonded into a whole. The patch layer is attached to the inner side of the cement layer. The patch layer comprises a plurality of ceramic patches and an ore powder layer coated among the ceramic patches. The ore powder layer contains cement and natural ore powder capable of releasing far red line, i.e. negative ions, which are uniformly mixed. The tripod body is mainly matched with a steam generating device for use. The steam generated by the steam generating device can be sent into the tripod body to heat the natural mineral powder of the mineral powder layer, so that the natural mineral powder releases far infrared rays and negative ions to perform steam physical therapy on people sitting in the tripod body.

Description

Tripod body structure of steam physiotherapy device

Technical Field

The invention relates to a tripod body structure of a steam physiotherapy device, which is characterized in that a glass fiber which can not generate radioactive substances is used for manufacturing a shell of the tripod body, so that after steam enters the tripod body, only an ore patch can generate energy, the energy generated by the tripod body at high temperature can be easily set, and the safety range is within a safe range.

Background

Modern people easily thicken and harden vessel walls and cause cardiovascular diseases due to the fact that the modern people eat excessive high-protein and high-cholesterol foods for a long time and lack of exercise for a long time. Furthermore, the increase in age of human blood vessels and the decrease in metabolic capability also cause the thickening and hardening of blood vessel walls, resulting in cardiovascular diseases. In addition, some diseases related to metabolism and blood circulation, such as myocardial infarction, stroke, etc., are related to angiosclerosis.

In the current medical technology, the thickened and hardened blood vessel wall cannot be thinned and softened again. Proper exercise is one of the ways in which cardiovascular disease can be ameliorated. In addition to the increase in the heartbeat above 120 during strenuous exercise, a large amount of sweat is discharged by muscle compression. After strenuous exercise, toxins such as lipid peroxide in the blood vessel wall are contained in a human body and are discharged out of the body from sweat glands along with sweat through capillaries, so that the blood vessels are gradually softened and recovered to be healthy. However, the elderly with high qi deficiency and the patients who are not fit well can not do strenuous exercise to remove sweat and toxic substances, and the physical condition is worse and worse. Modern people have a steam bath in order to perspire in large quantities without exercise.

The heat source of the steam bath is hard to squeeze and permeate into the skin, and the sweat flowing out is called superficial sweat or deficient sweat. "Portable steam chest" disclosed in U.S. Pat. No.3,092,843 is a device capable of steam bathing, and the user can expel much of the superficial perspiration due to the heat of the steam.

The chinese patent application No. 201320001740.8 discloses a steam physiotherapy device, which utilizes the temperature of steam to make tourmaline patches release far infrared rays, i.e. negative ions. The negative ions can go deep into the human body along with the penetrating power of far infrared rays to promote the reduction of active oxygen and free radicals in the human body, and expand in the human body to extrude the body fluid in the human body, so that the deep toxins in the human body can be discharged out of the human body along with the body fluid from capillaries and sweat glands. The sweat discharged at this time is deep sweat. Therefore, the negative ions penetrating into the body can reduce lipid peroxide to repair cells. Toxins excreted with the deep sweat comprise waste products blocking blood vessels and lymph. When the blockage of the blood vessel is discharged out of the body, the blood vessel is naturally and gradually softened, the blood circulation effect returns to normal, and the body naturally recovers to be healthy.

The urn body of the steam physiotherapy device between the workshops is made by firing in a pottery clay kiln. The pottery clay is made by high temperature kiln firing and has radioactivity. Namely, the pottery jar can release far infrared ray at the temperature of about 40 ℃. When the far infrared ray dosage is too large, radioactive substances harmful to human bodies are formed. And the artificial tourmaline stuck in the urn body of the workshop is made of anion powder, can release far infrared rays and anions, but also can generate radioactive radiation of more than 1000 microns of Schiff (which can be borne by a human body for one year), and is harmful to human health.

Disclosure of Invention

The present invention provides a tripod structure of a steam physiotherapy device, which uses glass fiber as the outer layer of the tripod, and does not release radioactive substances, so that the tripod structure is safer to use.

The invention provides a tripod structure of a steam physiotherapy device, which comprises: a basin-shaped base and a cylindrical tripod body with openings at two ends. The tripod body is arranged above the base and spliced into a complete tripod body. The tripod body further comprises a door which can be opened and closed. The outer layer of the tripod body and the base is a glass fiber layer, the middle layer is a cement layer, and the inner layer is a patch layer. The cement layer of the middle layer and the glass fiber layer of the outer layer are bonded into a whole. The patch layer of the inner layer is attached to the inner side of the cement layer. The patch layer comprises a plurality of ceramic patches and an ore powder layer coated among the ceramic patches. The ore powder layer contains cement and natural ore powder capable of releasing far red line, i.e. negative ions, which are uniformly mixed. The glass fiber layer has no radioactivity and absolute safety.

A plurality of small stone blocks are adhered to the inner side wall surfaces of the glass fiber layers of the tripod body and the base. The cement layer can cover the small stones and can be connected with the glass fiber layer into a whole.

The bottom of the base is only provided with a glass fiber layer and a cement layer.

The bottom surface of the tripod body is provided with a convex strip. The top surface of the base is oppositely provided with a groove. The convex strips on the bottom surface of the tripod body are relatively clamped into the grooves on the top surface of the base, so that the tripod body is prevented from shifting.

Drawings

Fig. 1 is an external view of an embodiment of the present invention.

FIG. 2 is a state diagram of the door opening of the embodiment shown in FIG. 1.

Fig. 3 is an exploded view of the tripod body and the base.

Fig. 4 is a partial sectional view of the tripod body.

Fig. 5 is a partial cross-sectional view of another embodiment of the tripod body.

Fig. 6 is a partial cross-sectional view of another embodiment of a base.

Fig. 7 is a sectional view of a spliced part of the tripod body and the base in another embodiment.

FIG. 8 is a diagram of the present invention with a steam inlet pipe, a baffle, and a stool.

Description of reference numerals: 1-an ancient cooking vessel body; 2-a steam input pipe; 3-a flow guide plate; 4-stool; 10-a tripod body; 11-a glass fiber layer; 111-small stone blocks; 12-a cement layer; 13-a patch layer; 131-ceramic patches; 132-a layer of ore fines; 14-a door; 15-convex strips; 20-a base; 21-a glass fiber layer; 211-small stone; 22-. a cement layer; 23-a patch layer; 231-ceramic patches; 232-a layer of ore fines; 24-groove; 25-foot.

Detailed Description

Please refer to fig. 1, fig. 2, and fig. 8. The vessel body structure of the steam physiotherapy device disclosed by the invention is mainly matched with a steam generating device (not shown in the figure) for use. Steam generated by the steam generating device can be sent into the tripod body 1 through the steam input pipe 2 to heat the inner wall surface of the tripod body 1. In conjunction with fig. 4. The inner wall surface is provided with ceramic patches 131, and an ore powder layer 132 is coated between the ceramic patches 131. The natural ore powder in the ore powder layer 132 can release far infrared rays and negative ions at a temperature above 30 ℃ to perform steam physiotherapy on a person sitting in the tripod body 1. A guide plate 3 is arranged in the tripod body 1, and a stool 4 is arranged on the guide plate 3 for a user to sit on. The steam sent from the steam input pipe 2 ascends upwards through the gap between the guide plate 3 and the inner wall surface of the tripod body 1 to heat the

ore powder layers

131 and 231 on the inner wall surface of the tripod body, so that the

ore powder layers

131 and 231 release negative ions and far infrared rays.

The tripod body 1 comprises: a basin-shaped base 20 and a cylindrical tripod body 10 with two open ends. The base 20 has three legs 25, forming the legs 25 of the tripod body 1. The tripod body 10 is arranged above the base 20 and spliced into a complete tripod body 1. The vessel 10 further includes a door 14 that can be opened and closed.

The peripheral wall of the tripod body 10 is composed of an outer layer, a middle layer and an inner layer. Wherein, the outer layer is a glass fiber layer 11 made of glass fiber; the middle layer is a cement layer 12 made of cement; the inner layer is a patch layer 13. The patch layer 13 includes a plurality of ceramic patches 131 and an ore powder layer 132 coated between the ceramic patches 131. The cement layer 12 of the middle layer is bonded with the glass fiber layer 11 of the outer layer into a whole. The inner patch layer 13 is attached to the inner side of the cement layer 12. The ore powder layer 132 includes cement and natural ore powder capable of releasing far red line, i.e. negative ions, which are uniformly mixed.

The peripheral wall of the base 20 is also composed of an outer layer, a middle layer and an inner layer. Wherein the outer layer is a glass fiber layer 21 made of glass fiber; the middle layer is a cement layer 22 made of cement; the inner layer is a patch layer 23. The patch layer 23 includes a plurality of ceramic patches 231 and an ore powder layer 232 coated between the ceramic patches 231. The middle cement layer 22 is bonded with the outer glass fiber layer 21. The inner patch layer 23 is attached to the inside of the cement layer 22. The ore powder layer 232 contains cement and natural ore powder capable of releasing far red line, i.e. negative ions, which are mixed uniformly. The bottom surface of the base 20 is composed of only an outer layer 21 and a middle layer 22.

The natural ore powder in the ore powder layers 132 and 232 of the patch layers 13 and 23 of the tripod body 10 and the base 20 has the characteristic of releasing negative ions and far infrared rays when being heated. The natural ore powder may be powder obtained by grinding 708 tourmaline from Japan, or powder obtained by grinding natural ore capable of releasing negative ions and far infrared rays. These minerals are rare natural minerals produced over hundreds of millions of years and can release far infrared rays (positive potential) and negative ions (negative potential) simultaneously without emitting radioactive radiation.

The

ceramic patches

131 and 231 are provided on the patch layers 13 and 23, respectively, to reinforce the strength of the inner wall surfaces of the vessel body 10 and the base 20. This is as if tiles were attached to the walls of the building. In addition, the coating area of the ore powder layers 132 and 232 can be reduced, the usage amount of the natural ore powder can be reduced, and the cost is reduced.

The natural ore powder in the ore powder layers 132 and 232 releases negative ions and far infrared rays when heated. The natural ore powder can release far infrared rays and negative ions when meeting the heat of the steam. The negative ions can go deep into the human body along with the penetrating power of the far infrared rays, so that active oxygen and free radicals in the human body are reduced, and deep sweat in the human body flows out of the human body.

The traditional urn body is made of pottery clay, so the weight is heavier, and the difficulty in carrying is increased. The invention uses glass fiber to make the glass fiber layers 11 and 21 of the outer layers of the tripod body 10 and the base 20, and compared with the traditional urn body outer layer made of pottery clay, the invention can reduce the whole weight of the tripod body 1 and is relatively easy to carry. It is made up by using clay through the processes of high-temp. kiln firing and radioactive radiation. The urn body fired with pottery clay generates excessive far infrared rays (more than 1000 micro-siever which can be endured by human body for one year) under the high temperature of steam (about 40 ℃), and forms harmful radioactive radiation. When a person sits in the pottery tripod body for 20-30 minutes, the pores of the body expand when the person is heated, and the energy radiated by radioactivity directly enters the capillaries to oxidize the walls of the capillaries so as to prevent the capillaries from hardening and harm the health of the body. Therefore, although the ceramic products are suitable for being used as common household utensils, the ceramic products are not suitable for being used as the tripod body of the steam physiotherapy device. The glass fiber layers 12 and 22 of the tripod body 1 of the invention have no radioactivity and absolute safety.

Refer to fig. 3 and 6. The bottom surface of the tripod body 10 is provided with at least one convex strip 15. The top surface of the base 20 is oppositely provided with at least one groove 24. The convex strips 15 on the bottom surface of the tripod body 10 are relatively clamped into the grooves 24 on the top surface of the base 20, so that the tripod body 10 can be prevented from shifting. In this embodiment, five protruding strips 15 with different lengths are disposed on the bottom surface of the tripod body 10. The top surface of the base 20 is opposite to five grooves 24 with different lengths. The convex strips 15 on the bottom surface of the tripod body 10 are arranged on the bottom surface of the cement layer 12. Similarly, the groove 24 in the top surface of the base 20 is disposed on the top surface of the cement layer 22.

Since the expansion coefficients of the glass fiber layers 11 and 21 and the cement layers 12 and 22 are different from each other, the cement layers 12 and 22 may crack or the glass fiber layers 11 and 21 may deform in the tripod body 1 after long-term use. In order to ensure a long service life of the tripod body 1, the length change caused by thermal expansion and contraction must be divided into a plurality of blocks to reduce the deformation length per unit area, so as to avoid the deformation of the glass fiber layers 11 and 21 and the cement layers 12 and 22 caused by thermal expansion and contraction. Please refer to fig. 5-7 for another embodiment. A plurality of

small stones

111, 211 are adhered on the inner side wall surfaces of the tripod body 10 and the glass fiber layers 11, 21 of the base 20. The cement of the cement layer 12 can be integrally connected to the glass fiber layers 11 and 21 so as to cover the

small blocks

111 and 211. The cement layers 12 and 22 are divided into thousands of small blocks by thousands of small stones 111 and 121, and when the deformation length of each small block is extremely small, the cement layers 12 and 22 are not cracked, the glass fiber layers 11 and 21 are not deformed, and the durability of the tripod body 1 is relatively improved.

The vessel 1 is combined with a steam generating device (not shown in the figures) and a steam delivery pipeline (not shown in the figures) to form a steam physiotherapy device. The steam generated by the steam generating device is sent to the steam input pipe 2 in the tripod body 1 through the oil steam conveying pipeline. The steam from the steam input pipe 2 will heat the

ore powder layer

132, 232, so that the natural ore powder can release far infrared ray and negative ions.

Far infrared energy can permeate under the skin to promote blood circulation. The negative ions can go deep into the human body along with the penetrating power of far infrared rays to promote the reduction of active oxygen and free radicals in the human body, and expand in the human body to extrude the body fluid in the human body, so that the deep toxins in the human body can be discharged out of the human body along with the body fluid from capillaries and sweat glands. The sweat discharged at this time is deep sweat. Therefore, the negative ions penetrating into the body can reduce lipid peroxide to repair cells. Toxins excreted with the deep sweat comprise waste products blocking blood vessels and lymph. When the blockage of the blood vessel is discharged out of the body, the blood vessel is naturally and gradually softened, the blood circulation effect returns to normal, and the body naturally recovers to be healthy. When the body circulation function is good, the immunity is naturally improved.

In conclusion, the tripod body structure of the steam physiotherapy device provided by the invention does not generate radioactive glass fibers to manufacture the

outer layers

11 and 21 of the tripod body 1, has light weight compared with the prior art, does not have radioactivity and has high safety. The surface of the tripod body 1 can be sprayed with colored paint, so that the overall appearance is smooth and attractive.

The foregoing description is intended to be illustrative rather than limiting, and it will be appreciated by those skilled in the art that many modifications, variations or equivalents may be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims

1. A tripod structure of a steam physiotherapy device comprises: the tripod comprises a basin-shaped base and a cylindrical tripod body with openings at two ends; the tripod body is arranged above the base and spliced into a complete tripod body; the tripod body also comprises a door which can be opened and closed; the method is characterized in that:

the outer layer of the peripheral wall of the tripod body and the base is a glass fiber layer, the middle layer is a cement layer, and the inner layer is a patch layer; the glass fiber layer is made of glass fibers; the cement layer of the middle layer and the glass fiber layer of the outer layer are bonded into a whole; the patch layer of the inner layer is attached to the inner side of the cement layer; the patch layer comprises a plurality of ceramic patches and an ore powder layer coated among the ceramic patches; the ore powder layer can fix the ceramic patches; the ore powder layer contains cement which is uniformly mixed and natural ore which can release far red lines and negative ions; the bottom of the base is only provided with a glass fiber layer and a cement layer.

2. The vessel structure of a vapor physiotherapy device as claimed in claim 1, wherein the vessel body is provided with a convex strip on the bottom surface; the top surface of the base is oppositely provided with a groove; the convex strips on the bottom surface of the tripod body are relatively clamped into the grooves on the top surface of the base, so that the tripod body is prevented from shifting.

3. The tripod body structure of steam physiotherapy device of claim 2, wherein the convex strips on the bottom surface of the tripod body are arranged on the bottom surface of the cement layer; the groove on the top surface of the base is arranged on the top surface of the cement layer.

4. The tripod body structure of steam physiotherapy device of claim 1, wherein the inner side wall surface of the inner layer of glass fiber layer is adhered with a plurality of small stone blocks; the cement of the cement layer can coat the small stones and can be connected with the glass fiber layer into a whole.

5. The vessel structure of steam physiotherapy device of claim 4, wherein the bottom surface of the vessel is provided with a convex strip; the top surface of the base is oppositely provided with a groove; the convex strips on the bottom surface of the tripod body are relatively clamped into the grooves on the top surface of the base, so that the tripod body is prevented from shifting.

6. The tripod body structure of steam physiotherapy device of claim 5, wherein the convex strips on the bottom surface of the tripod body are arranged on the bottom surface of the cement layer; the groove on the top surface of the base is arranged on the top surface of the cement layer.