KR950005059Y1 - Rice miller have infrared lamp - Google Patents

Abstract

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Description

Pottery with Far Infrared Lamp

1 is a cross-sectional view showing the configuration of a jeongjeonggwa equipped with a far infrared lamp of the present invention.

2 is a cross-sectional view of the present invention.

Figure 3 is an enlarged cross-sectional view of the grain outlet of the present invention mill.

* Explanation of symbols for main parts of the drawings

100: Expected 200: Municipal Assembly

210: first milling chamber 220: second milling chamber

230: 3rd mill room 240: 4th mill room

600,700,800: Far Infrared Lamp

The present invention relates to a potter to peel and polish various grains, and more particularly to a potter with far-infrared rays that can extend the storage period by maintaining sterilization effect and freshness on the grain (mainly rice).

In recent years, many types of grain-cutting and polishing have been used in air-circulating pots. Various kinds of such pottery have been developed and used until now, and in general, much research and efforts have been made to improve the structure to preserve the original appearance without breaking the grain and to perform the desired stripping and polishing processes more effectively. For example, US Pat. Nos. 4,292,890 and 5948407. This milling mechanism has a milling chamber in which a cam-shaped polishing rotor is rotatably installed in a polygonal tubular screen which is installed in an upright state, and a screw-type conveying means is continuously installed below the milling chamber. Such a potter's wheel pushes the grain coming in through the grain inlet provided at one side of the bottom of the mill to the polishing rotor, and the grain is pushed along the gap provided between the polishing rotor and the conveying means. As it rises, the grain is peeled or the surface of the grain is polished by the friction action that occurs in the gap between the polishing rotor and the screen.

In this way, the potter's tools are developed to maximize the process efficiency of the peeling and polishing process of grain husks.

By the way, it is very important to store the polished and polished grains (which are mainly described here for rice) while maintaining the original state without deterioration by using the above-described cutting mechanism. Currently, the storage method of grain is usually stored using a drying method, but the drying condition of the grain (moisture content less than 5%) is not good, so the storage period is not long and there is a problem that the grain loses its original state for long term storage. In other words, the grain is not maintained in its original state due to the partial removal of the inner and outer grains of the grains without uniform removal of the moisture contained in the grains inside and outside the grains. In the state of holding a little, inevitably rubs grain, and performs the desired stripping and polishing process. At this time, the friction applied to the grains raises the temperature of the grains, and the deterioration of the grains releases the moisture in the grains to the outside. Drying of the epidermis of the grain and partial drying of the grain causes cracking on the epidermis of the grain, and bacterial propagation is activated by moisture in the grain, thereby easily changing the grain. In addition, the freshness of the grain, as well as the taste of the fall, the grain maintenance is poor, leading to a low grain preservation, there is a lot of defects such as fading and deterioration of the grain during long-term storage.

The present invention has been made in consideration of the above circumstances, and its purpose is to release the water molecules contained in the polished rice at far-infrared wavelengths so as to effectively carry out the dry state of the rice and prevent the grain from being deteriorated. A simple and effective far-infrared lamp having a sterilizing effect is provided. In particular, another object of the present invention is to provide a potter's wheel with a far-infrared lamp that maintains the freshness of the grain to improve its preservation and allow long-term storage.

Another object of the present invention is to provide a potter's wheel equipped with a far-infrared lamp that can preserve grain in its original state to prevent deterioration and maintain taste.

The object of this invention is achieved by peeling the grains of the grain and polishing the surface of its grains, i.e. by providing a potter to use the abrasive rotor, which is composed of the base and the chamber assembly. The chamber assembly is a substantially cylindrical vertical assembly which is divided into first, second, third and fourth milling chambers, the milling chambers of which are connected to each other in series with suitable fittings. The first part of the milling chamber has a round inner cylinder and is freely rotatable using a pair of bearings, and a motor for driving the shaft is installed outside the first milling chamber. It is connected to a suitable drive transmission member, and an air outlet is provided in the first chamber. The second part is installed on the first milling chamber, and the cylindrical tube through which the rotating shaft passes is installed, and in the cylindrical tube there is a hollow screw-type conveying means for conveying grain, at which point the second milling chamber ends along the rotating shaft. It is integrally fitted and provided to cooperate. In addition, a screw-type injection means for forcibly pushing grain into the second grinding chamber is installed in a horizontal direction intersecting with the second grinding chamber at a lower portion of the second grinding chamber, and the injection means is driven by another motor. I'm getting it. The third milling chamber is installed on the second milling chamber in succession, and is fitted to the rotary shaft so that the polishing rotor is rotated in a polygonal tubular screen assembly installed with some space in the side wall of the cylindrical tubular body with a predetermined gap. do. The third milling chamber is also provided with a far infrared ray lamp along the axis of rotation in a rotary shaft corresponding to the third milling chamber, and at least one further infrared lamp is provided in the space provided in the third milling chamber. The fourth milling chamber is installed at the upper end of the screen assembly of the third milling chamber, and is provided with a grain outlet, the grain outlet of which is opened and closed by a lid. And another infrared lamp is installed at the proper place of grain outlet in the fourth milling room. Therefore, far-infrared rays are sprayed on the grains of the milling and polishing process to maintain sterilization effect and freshness for a long time, thereby increasing the preservation of grains.

Next, embodiments of the present invention will be described in detail with reference to the drawings. 1 is a detailed view of a pot with a far infrared lamp according to the present invention, which is composed of a base 100 and a chamber assembly 200. The milling assembly 200 is a substantially cylindrical vertical assembly and is divided into a first milling chamber 210, a second milling chamber 220, a third milling chamber 230, and a fourth milling chamber 240. The milling chambers are connected to each other in series with suitable fasteners. The first milling chamber 210 of the milling chamber assembly 200 has an inner cylinder 211 formed in a substantially hopper shape and can freely rotate the hollow rotating shaft 300 by using a pair of bearings 212 and 213. Is installed. At this time, the rotating shaft 300 is installed through the central part of the second and third milling chambers from the first milling chamber to the upper end of the third milling chamber, and the rotary shaft ( A motor 400 for driving 300 is installed and connected to the rotating shaft and an appropriate drive transmission member 401. The air outlet 214 is provided downward in the lower part of the first milling chamber 210.

The second milling chamber 220 is installed on the first milling chamber 210 and is provided with an inner cylinder 221 through which the rotating shaft 300 passes. The inner cylinder 221 is pressurized with grain to form a third milling chamber. Screw-type feed means 222 pushing up to the 230 is installed along the rotation axis 300 to the end of the second milling chamber, the lower part of the second milling chamber 220 grain to be milled to the second milling chamber 220 The hopper-shaped injection means 500 which naturally pushes in by the weight is provided in the horizontal direction intersecting with the second milling chamber.

The third milling chamber 230 is continuously installed in the upper part of the second milling chamber 220, and maintains some space 232 in the substantially cylindrical sidewall 231, and the screen assembly 233 is installed therein. The polishing rotor 234, which is in direct contact with the grain and is polished and polished, is connected to the upper end of the rotating shaft 300 and installed on the concentric shaft. At this time, as the grains pass through the gap provided between the polishing rotor 234 and the screen assembly 233, the shells of the grains are peeled off by the friction action generated in the gaps, and the polishing process is performed.

In addition, the space 232 provided between the screen assembly 233 and the side wall 231 of the third milling chamber 230 is a device for extracting wind power such as shells or grains of grain generated during milling and polishing. At least one far-infrared lamp 600 will be installed at equal intervals while providing a passage that is sucked out by the air pressure generated in the air, and the space around the screen assembly 233 as shown in FIG. . The far-infrared lamp 600 is fixedly installed in the space as a pair of supports 601 above and below the inner circumferential wall of the side wall 231.

In addition, the far-line lamp 700 is fixed to the support 701 along the polishing rotor in the inner center of the polishing rotor 234 of the third milling chamber 230. Far-infrared rays radiated from the far-infrared lamp 700 of the far-infrared lamp are irradiated to the grains of the milling process through the air vents provided in the main wall of the polishing rotor.

The fourth milling chamber 240 is installed at the upper end of the screen assembly 233 of the third milling chamber 230, and a grain outlet 241 is provided at one side of the third milling chamber 230 for discharging grains of the milling and polishing processes. It is intended to be opened and closed with a lid 242. In addition, the far-infrared lamp 800 is installed at the bottom of the bottom of the grain discharge port 241 in the horizontal direction crossing the traveling direction of the discharged grain.

4, the grain outlet 241 is shown in detail. That is, the bottom 242 of the grain outlet 241 is provided with a projection window 243 having a height equal to the bottom surface in the width direction in the width direction of the width or substantially the same as the bottom width. Its projection window (243) will provide a projection path for passing the far infrared rays generated from the far infrared lamp 800 will be irradiated with far infrared rays to the grain flowing to the bottom of the grain outlet. Far-infrared lamp 800 is installed hanging by a pair of supports 801 which are installed on both sides of the bottom bottom of the grain outlet 241.

The operation of the calibrator with far infrared lamp will now be described with reference to FIGS. 1, 2 and 3. When the grains to be milled and polished are forced into the second milling chamber by the injection means 500 provided in the lower part of the second milling chamber 220, the second milling chamber connected to the milling means is transported ( 222 pushes the grain to the third milling chamber 230 by the rotational force of the screw. At this time, the conveyed grain is subjected to the primary coating by friction against the inner peripheral wall of the blade and the inner cylinder 221 of the conveying means. In these primary mills, preliminary milling processes are carried out to the extent that the shells of the grain are added. The grains formed in this primary mill are forcibly pushed up from the second mill by the transfer means to the third mill 230 and pass through the gap provided between the screen assembly 233 and the polishing rotor 234. While the secondary works are flooded by the friction action generated in this gap, the grains and husks of the grains are completely detached to complete the cutting work, and the shells generated during the second coating are the space 232 of the third coating room 230. ) And the second and first milling chambers are sucked into the air outlet 214, and the grains are discharged through the grain outlets 241 of the fourth milling chamber 240. By repeatedly performing such a coating process, the desired coating and polishing process is achieved.

The method of accomplishing the cutting operation while passing through the second, third, and fourth milling chambers is the same method as in the milling mechanism in which the conventional mechanical elements have a vertical arrangement.

In the present invention, at least one far-infrared lamp 600 is installed in the space 232 provided between the side wall 231 of the third milling chamber 230 and the screen assembly 233 during the milling and polishing of grain. Or another far-infrared lamp 700 in the polishing rotor 230 to the far-infrared ray to the grain forming the polishing process, and to reach the upper, inner, side third milling chamber 230 of the hollow rotating shaft 300 By installing far-infrared rays from inside and outside of the third milling chamber to the grains that make up the milling process. It also promotes the removal of the cause of the deterioration, and this suppression prevents the grain from decaying and maintains freshness, thus keeping it intact for a long time without damaging the grain. There is an advantage that can improve the inertia of course, does not lose the taste.

In addition, another far-infrared lamp 800 is provided at the bottom of the grain discharge port 241 of the fourth milling chamber 240, and the far-infrared rays are repeatedly applied to the grains of the grains for which the milling and polishing process is completed, thereby providing the desired sterilization effect. It is effective to get freshness.

In addition, the present invention may allow the far infrared lamp to be installed in each of the third and fourth milling chambers 230 and 240 as described above, and selected from any one of the third and fourth milling chambers. You can also install it.

Although the embodiments of the present invention have been described so far, the present invention is not limited thereto and may be modified within the scope of the invention as described in the claims.

Claims (4)

A first milling chamber having an inner cylinder provided with a rotating shaft, and a fourth milling chamber equipped with second and third milling chambers and grain outlets, each of which is provided with a feeding means and a grinding rotor along the rotary shaft, on top of the first milling chamber; And a far-infrared lamp provided with a far-infrared lamp for disinfecting and maintaining freshness by sprinkling far-infrared rays in grains of the milling and polishing process in each of the third and fourth mills. Pottery. 2. The far-infrared ray beam according to claim 1, wherein at least one far-infrared lamp is provided at equal intervals with a pair of supports along the polishing rotor at a suitable space provided between the side wall of the third chamber and the screen assembly. Potter with lamp. 3. The potentiometer according to claim 2, further comprising a far infrared lamp provided as a pair of supports in the polishing rotor of the third potting chamber. 4. The potter's wheel according to claim 3, further comprising: a viewing window in a transverse direction intersecting the grain discharging direction at the bottom of the discharge port bottom of the fourth yard, and a far infrared lamp supporting the lower portion of the viewing window.