CN215150201U - Processing equipment of far infrared ray household utensils - Google Patents

Abstract

The utility model relates to a processing device of far infrared ray household utensils, which mainly solves the problem of poor processing quality stability of the far infrared ray household utensils in the prior art, and comprises a radiation chamber, a heat preservation chamber, a heater, a far infrared ray source and an exhaust fan, wherein the heat preservation chamber is internally provided with an upper clapboard and a lower clapboard, the heat preservation chamber is divided into an upper flow guide chamber, a working chamber and a lower flow guide chamber through the upper clapboard and the lower clapboard, through holes are respectively arranged on the upper clapboard and the lower clapboard, the heat preservation chamber is respectively provided with an air inlet communicated with the working chamber, an upper air outlet communicated with the upper flow guide chamber and a lower air outlet communicated with the lower flow guide chamber, a door leaf is arranged on one side surface of the heat preservation chamber and positioned in the working chamber, a plurality of air guide covers are distributed at intervals on the side surface, each air guide cover is provided with at least one row of air vents along the vertical direction, the air inlet is communicated with each air guide cover through a connecting pipe, the radiation chamber is provided with an inlet and an outlet, the heater is arranged in the radiation chamber, and the far infrared radiation source is arranged on the heater.

Description

Processing equipment of far infrared ray household utensils

Technical Field

The utility model relates to a processing device of ceramic catering utensils, in particular to a processing device of far infrared ray utensils.

Background

The far infrared ray has strong penetrating power and radiation power, has obvious temperature control effect and resonance effect, and is easy to be absorbed by object and converted into internal energy of object. After the far infrared rays are absorbed by human bodies, water molecules in the bodies can resonate, so that the water molecules are activated, the intermolecular binding force of the water molecules is enhanced, biological macromolecules such as protein and the like are activated, and the cells of the organisms are at the highest vibration energy level. Because the biological cells generate resonance effect, the far infrared heat energy can be transferred to the deeper part of the human skin, the temperature of the lower deep layer rises, and the generated heat is emitted from inside to outside. The strength of the action can expand blood capillary, promote blood circulation, strengthen metabolism among tissues, increase regeneration capacity of tissues, improve immunity of organisms and regulate mental abnormal excitation state, thereby playing a role in medical care. Therefore, more and more manufacturers apply far infrared rays to products in business to improve the quality of the products.

For the field of ceramic catering utensils, manufacturers usually mix materials capable of radiating far infrared rays with specific wavelengths into preparation materials, and produce far infrared ceramics by changing the original preparation process, for example, high negative ion and far infrared materials such as tourmaline, medical stone in the deep mountains, guiyang stone, volcanic rock and the like are mixed with ceramic materials with various purposes according to different proportions, and the ceramic ware carries the far infrared rays by the way, but the mixing cost is changed, the original production process flow needs to be improved, and the mixed materials are expensive, so that the production cost of the product is greatly improved, and the manufacturers lose market competitive advantages.

Currently, chinese patent application No.: 201020171320.0 discloses a processing device of far infrared ceramic tableware, which comprises a radiation chamber, a far infrared radiation source, a heater, a fan, a power switch, an air supply channel and a heat preservation chamber; one side of the radiation chamber is connected with the heat preservation chamber through an air supply channel, and the other side of the radiation chamber is provided with a fan; a far infrared ray source and a heater are arranged in the radiation chamber and between the air supply channel and the fan; a grid for placing ceramic catering appliances conveniently is arranged in the heat preservation chamber, and a door leaf for placing and taking out the ceramic catering appliances conveniently is arranged on the side wall of the heat preservation chamber; the heater and the fan are connected with a working power supply through a power switch. It is attached to ceramic ware through the far infrared that produces for carry the far infrared, thereby manufacturing cost has been reduced, however, the processing equipment of this kind of structure blows in the heat preservation indoor through the fan air blast with the indoor hot-air that radiates in, makes the interior ceramic ware of heat preservation and this hot-air contact that carries the far infrared, form the heat transfer, because heat preservation room and radiation room are in the encapsulated situation, under the fan effect, make the interior hot-air of heat preservation form turbulent state, cause the homogeneity of the far infrared that the interior ceramic ware of heat preservation carried poor, cause product quality unstability.

SUMMERY OF THE UTILITY MODEL

Therefore, to foretell problem, the utility model provides a processing equipment of far infrared household utensils, it has mainly solved the poor problem of processing quality stability of far infrared household utensils among the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a processing device of a far infrared ray vessel comprises a radiation chamber, a heat preservation chamber, a heater, a far infrared ray radiation source and an exhaust fan, wherein an upper partition plate and a lower partition plate are arranged in the heat preservation chamber, the heat preservation chamber is divided into an upper flow guide chamber, a working chamber and a lower flow guide chamber through the upper partition plate and the lower partition plate, through holes are formed in the upper partition plate and the lower partition plate, an air inlet communicated with the working chamber, an upper air outlet communicated with the upper flow guide chamber and a lower air outlet communicated with the lower flow guide chamber are respectively formed in the heat preservation chamber, a door leaf is arranged on one side face of the heat preservation chamber, a plurality of air guide covers are distributed on the side face at intervals, the air guide covers are distributed along the vertical direction and are arranged in parallel to each other, at least one row of air holes are formed in the air guide covers along the vertical direction, the air inlet is communicated with the air guide covers through a connecting pipe, an inlet and an outlet are formed in the radiation chamber, the upper air outlet and the lower air outlet are communicated with an inlet of the radiation chamber through a first air pipe, the exhaust fan is arranged on the first air pipe, the air inlet is communicated with an outlet of the radiation chamber through a second air pipe, the heater is arranged in the radiation chamber, and the far infrared radiation source is arranged on the heater.

Furthermore, the connecting pipe comprises an upper cap body which is respectively covered on the upper end of each air guide cover, a lower cap body which is respectively covered on the lower end of each air guide cover, an upper pipe body which is connected with two adjacent upper cap bodies, a lower pipe body which is connected with two adjacent lower cap bodies, and a connecting part which is respectively connected with one of the upper pipe bodies and one of the lower pipe bodies.

Furthermore, three rows of air holes are arranged on each air guide cover.

Furthermore, the middle part arch of air guide cover is equipped with the bellying, the bellying distributes along the length direction of air guide cover, the cross section of bellying is isosceles trapezoid structure, and each row the bleeder vent distributes respectively on the upper base and the waist of bellying.

Furthermore, a plurality of grids for containing vessels are arranged in the working chamber, and two air holes are distributed on each air guide cover and positioned between two adjacent grids.

By adopting the technical scheme, the beneficial effects of the utility model are that: the processing equipment of the far infrared ray ware heats the far infrared ray source through the heater, when the temperature reaches 60 ℃, the far infrared ray source generates a large amount of far infrared rays through the heat effect, the work of the exhaust fan is realized, the hot air containing the far infrared rays in the radiation chamber enters into each air guide cover through the second air pipe, the air inlet and the connecting pipe, and is discharged through the row-shaped air holes which are arranged on the air guide covers and distributed vertically, the hot air uniformly covers the ware in the work chamber inwards along the horizontal direction, so that each ware is heated uniformly, and through the through holes on the upper partition plate and the lower partition plate, the hot air in the work chamber forms upper and lower shunt to enter into the upper diversion chamber and the lower diversion chamber, and enters into the radiation chamber through the first air pipe to carry out secondary heating, the design mode is realized, so that the hot air in the work chamber forms circulating air flow, the hot air is uniformly acted on the vessels distributed at all positions, so that the vessels in the same batch placed in the heat preservation chamber are good in contact uniformity with the hot air, the processing quality is improved, and the stability of the processing quality is maintained; furthermore, the upper cap body, the lower cap body, the upper tube body and the lower tube body are arranged, so that the uniformity of the flow guide of hot air entering the air guide cover is good, the uniformity of hot air discharged from the air holes in the air guide cover is facilitated, the stability of the processing quality is further improved, the connection tube and the air guide cover are convenient to mount and dismount, and the maintenance and the replacement are facilitated; furthermore, the three rows of air holes are respectively distributed on the upper bottom and the waist of the bulge part to form diffusion distribution, so that annular air flow can be better formed to act on the vessel, and the heat exchange with the vessel is improved; furthermore, two air holes are distributed on each air guide cover and between two adjacent grids, so that the heating uniformity of the vessel on each grid is improved.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic top view of a heat-retaining chamber according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of the connection pipe and the air guide cover in the embodiment of the present invention.

Detailed Description

The present invention will now be further described with reference to the accompanying drawings and detailed description.

The embodiment of the utility model provides a do:

referring to fig. 1, 2 and 3, a far infrared ray ware processing device comprises a radiation chamber 1, a heat preservation chamber 2, a heater 3, a far infrared ray source 4 and an exhaust fan 5, wherein an upper partition plate 6 and a lower partition plate 7 are arranged in the heat preservation chamber 2, the heat preservation chamber 2 is divided into an upper diversion chamber 21, a working chamber 22 and a lower diversion chamber 23 by the upper partition plate 6 and the lower partition plate 7, through holes 8 are respectively arranged on the upper partition plate 6 and the lower partition plate 7, the through holes 8 on the upper partition plate 6 are distributed in the middle of the upper partition plate 6, the through holes 8 on the lower partition plate 7 are distributed in the middle of the lower partition plate 7, an air inlet 24 communicated with the working chamber 22, an upper air outlet 25 communicated with the upper diversion chamber 21 and a lower air outlet 26 communicated with the lower diversion chamber 23 are respectively arranged on the heat preservation chamber 2, a door leaf 9 is arranged on one side surface of the working chamber 22, and six air guide hoods 10 are distributed at intervals on the side surface, each air guide cover 10 is distributed along the vertical direction and arranged in parallel, each air guide cover 10 is provided with three rows of air holes 11 along the vertical direction, specifically, a projection 12 is convexly arranged at the middle part of the air guide cover 10, the projection 12 is distributed along the length direction of the air guide cover 10, the cross section of the projection 12 is of an isosceles trapezoid structure, each row of air holes 11 are respectively distributed at the upper bottom and the waist of the projection 12, the air inlet 24 is communicated with each air guide cover 10 through a connecting pipe 13, the radiation chamber 1 is provided with an inlet 101 and an outlet 102, the upper air outlet 25 and the lower air outlet 26 are communicated with the inlet 101 of the radiation chamber 1 through a first air pipe 14, the exhaust fan 5 is arranged on the first air pipe 14, the air inlet 24 is communicated with the outlet 102 of the radiation chamber 1 through a second air pipe 15, the heater 3 is arranged in the radiation chamber 1, and the far infrared rays 4 are arranged on the heater 3, four grids 16 for containing utensils are arranged in the working chamber 22, and two air holes 11 are distributed on each air guide cover 10 and between two adjacent grids 16.

In this embodiment, the connecting pipe 13 includes an upper cap body 131 covering the upper end of each air guide cover 10, a lower cap body 132 covering the lower end of each air guide cover 10, an upper pipe 133 connecting two adjacent upper cap bodies 131, a lower pipe 134 connecting two adjacent lower cap bodies 132, and a connecting portion 135 respectively connected to one of the upper pipe bodies 133 and one of the lower pipe bodies 134, the upper cap bodies 131 and the upper pipe bodies 133 are disposed in the upper diversion chamber 21, and the lower cap bodies 132 and the lower pipe bodies 134 are disposed in the lower diversion chamber 23.

The far infrared ray radiation source 4 may be oxide film, alumina, silica, iron oxide, etc. with high far infrared ray radiation.

The utility model discloses a working method is: this processing equipment of far infrared ray household utensils, heat far infrared ray source 4 through heater 3, when the temperature reaches 60 ℃, far infrared ray source 4 produces a large amount of far infrared rays through the heat effect, work through air exhauster 5, the hot-air that contains far infrared in radiation room 1 passes through second trachea 15, air intake 24, connecting pipe 13 enters into each air guide cover 10, and discharge along vertical distribution's row form bleeder vent 11 through setting up on the air guide cover 10, the household utensils in the even along the horizontal direction inwards cladding studio 22 of hot-air, make each household utensils be heated evenly, and through-hole 8 on last baffle 6 and the lower baffle 7, make the hot-air that is located studio 22 form upper and lower reposition of redundant personnel and enter into upper water conservancy diversion room 21 and lower water conservancy diversion room 23, and enter into radiation room 1 through first trachea 14 and carry out the secondary heating, this kind of design, the hot air in the working chamber 22 forms a circulating airflow and uniformly acts on the utensils distributed at each position, so that the contact uniformity between the utensils of the same batch placed in the heat preservation chamber 2 and the hot air is good, the processing quality is improved, and the stability of the processing quality is maintained; the upper cap body 131, the lower cap body 132, the upper tube body 133 and the lower tube body 134 are arranged, so that the uniformity of the flow of hot air entering the air guide cover 10 is good, the uniformity of hot air discharged from the air holes 11 on the air guide cover 10 is facilitated, the stability of the processing quality is further improved, the connection tube 13 and the air guide cover 10 are convenient to mount and dismount, and the maintenance and the replacement are facilitated; the three rows of air holes 11 are respectively distributed on the upper bottom and the waist of the bulge part 12 to form diffusion distribution, so that annular air flow can be better formed to act on a vessel, and the heat exchange with the vessel is improved; two air holes 11 are distributed on each air guide cover 10 and between two adjacent grids 16, so that the heating uniformity of the utensils on each grid is improved.

While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (5)

1. The utility model provides a processing equipment of far infrared household utensils which characterized in that: the heat preservation device comprises a radiation chamber, a heat preservation chamber, a heater, a far infrared radiation source and an exhaust fan, wherein an upper partition plate and a lower partition plate are arranged in the heat preservation chamber, the heat preservation chamber is divided into an upper flow guide chamber, a working chamber and a lower flow guide chamber through the upper partition plate and the lower partition plate, through holes are formed in the upper partition plate and the lower partition plate, an air inlet communicated with the working chamber, an upper air outlet communicated with the upper flow guide chamber and a lower air outlet communicated with the lower flow guide chamber are formed in the heat preservation chamber respectively, a door leaf is arranged on one side face of the heat preservation chamber, a plurality of air guide covers are distributed on the side face of the heat preservation chamber at intervals, the air guide covers are distributed in the vertical direction and are arranged in parallel to each other, at least one row of air holes are formed in each air guide cover in the vertical direction, the air inlet is communicated with the air guide covers through a connecting pipe, an air outlet inlet and an air outlet are formed in the radiation chamber, the upper partition plate is provided with an air guide cover, and an air outlet, The lower air outlet is communicated with an inlet of the radiation chamber through a first air pipe, the exhaust fan is arranged on the first air pipe, the air inlet is communicated with an outlet of the radiation chamber through a second air pipe, the heater is arranged in the radiation chamber, and the far infrared radiation source is arranged on the heater.

2. The processing equipment of far infrared ray vessel as set forth in claim 1, characterized in that: the connecting pipe comprises upper cap bodies respectively arranged at the upper ends of the air guide covers, lower cap bodies respectively arranged at the lower ends of the air guide covers, an upper pipe body connected with two adjacent upper cap bodies, a lower pipe body connected with two adjacent lower cap bodies, and connecting parts respectively connected with one of the upper pipe bodies and one of the lower pipe bodies.

3. The processing equipment of far infrared ray vessel as set forth in claim 1 or 2, characterized in that: three rows of air holes are arranged on each air guide cover.

4. The processing equipment of far infrared ray vessel as set forth in claim 3, characterized in that: the middle part arch of air guide cover is equipped with the bellying, the bellying distributes along the length direction of air guide cover, the cross section of bellying is isosceles trapezoid structure, and each row the bleeder vent distributes respectively on the last end and the waist of bellying.

5. The processing equipment of far infrared ray vessel as set forth in claim 4, characterized in that: the working chamber is internally provided with a plurality of grids for containing vessels, and two air holes are distributed on each air guide cover and between two adjacent grids.

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