KR20220008975A - Non-heating Typed Sesame Container for Preventing Carbonization by Using Air Suctong and Injection Before Storage - Google Patents

Abstract

The present invention relates to a non-heating type sesame storage device for preventing carbonization using air suction and air injection before storage. The non-heating type sesame storage device for preventing carbonization using air suction and air injection before storage, according to the present invention, comprises: a body part which stores sesame transferred through a specified transfer system after being roasted in a roasting pot before supplying the sesame to a storage device, wherein the body part stores, in an unheated state, the sesame transferred after being roasted at a specified completion temperature in the roasting pot; an injection module for forcibly injecting external air between the stored sesame at a specified injection pressure so as to rapidly cool, within a predetermined time period, a temperature of the sesame stored in the body part from a high temperature above a specified carbonization possible temperature in which sesame husk contained in the sesame can be carbonized to a low temperature below the carbonization possible temperature; an injection pressure unit which generates the specified injection pressure for forced injection of external air through the injection module and provides the generated injection pressure to the injection module; a suction module for forcibly sucking in air between the stored sesame at a specified suction pressure so as to rapidly cool, within a predetermined time period, the temperature of the sesame stored in the body part from the high temperature above the specified carbonization possible temperature in which sesame husk contained in the sesame can be carbonized to the low temperature below the carbonization possible temperature; a suction pressure unit which generates the specified suction pressure for forced suction of air between the sesame through the suction module and provides the generated suction pressure to the suction module; a discharge unit which discharges air between the stored sesame to the outside on the basis of the suction pressure and the injection pressure; and a supply unit which supplies the cooled sesame to the storage device.

Description

Non-heating Typed Sesame Container for Preventing Carbonization by Using Air Suctong and Injection Before Storage

The present invention maintains the temperature of the stored sesame during storage before being supplied to the storage device after being roasted through the stir-frying pot and then transferred through the designated transport system. In order to rapidly cool the sesame seeds to a low temperature below the carbonization temperature in a specified time within a specified time, external air is forcibly introduced between the stored sesame seeds at a specified input pressure, and the stored sesame air is forcibly sucked at a specified suction pressure, It relates to an unheated sesame storage device that prevents the shell from being further carbonized even in an unheated state.

Oil made by roasting and storing sesame seeds is used in many foods in Korea, but fake products or products that do not meet the standards are still in circulation.

In the case of storing oil using traditionally descended sesame seeds, roasted sesame seeds at a high temperature (about 230°C to 290°C) maximizes the oil flavor. The problem of exceeding

Korean Patent Application Laid-Open No. 10-2017-0030738 (published on March 20, 2017) relates to a method for manufacturing sesame oil and perilla oil that does not generate benzopyrene. Methods for preventing this from occurring are disclosed.

However, the prior patent removes benzopyrene in gaseous form in the process of roasting sesame seeds, and since it cannot remove carbides such as sesame shells or foreign substances that have been carbonized before sesame seeds, it is difficult to remove even benzopyrene remaining in carbides. there was.

In addition, after sesame seeds are roasted in a stir-fry pot, sesame grains or sesame grains are no longer carbonized in an unheated state. there was a problem that

An object of the present invention to solve the above problems is, during storage before supplying the sesame transferred through the designated transfer system to the storage device after being roasted through the stir-frying pot, the temperature of the stored sesame contained in the sesame In order to rapidly cool the sesame hull from a high temperature above the specified carbonization temperature that can be carbonized to a low temperature below the carbonization temperature within a specified time within a specified time, external air is forcibly introduced between the stored sesame at a specified input pressure, and the stored air between the stored sesame seeds is removed. It is to provide a storage device for unheated sesame so that the sesame hull is no longer carbonized even in an unheated state by forcibly sucking it at a specified suction pressure.

The non-heated sesame storage device that stores the sesame seeds transferred through the specified transfer system after being roasted through the stir-fried pot according to the present invention before supplying them to the storage device, after being roasted to a specified completion temperature through the stir-fry pot, the transferred sesame seeds The body part stored in an unheated state, and the temperature of the sesame stored in the body part is rapidly cooled within a specified time from a high temperature above the specified carbonization temperature capable of carbonization of the sesame husk contained in the sesame to a low temperature below the carbonization temperature An input module for forcibly inputting external air at a specified input pressure between the sesame seeds kept in storage, and an input pressure unit for generating a designated input pressure for forcibly inputting external air through the input module and providing it to the input module; In order to rapidly cool the temperature of the sesame stored in the body from a high temperature above the specified carbonization possible temperature of the sesame husk contained in the sesame to a low temperature below the carbonization temperature within a specified time, the air between the stored sesame seeds is sucked. A suction module for forcibly sucking in pressure, a suction pressure unit for generating a specified suction pressure for forcibly sucking the ground air through the suction module and providing it to the suction module, and the suction pressure and the input pressure. It may be configured to include a discharge unit for discharging the stored sesame seeds to the outside, and a supply unit for supplying the cooled sesame seeds to the storage device.

According to the present invention, the sesame seeds include sesame grains and sesame hulls in their original state or separated from sesame hulls less than a specified ratio, sesame kernels separated from sesame grains at a specified ratio or more, and sesame kernels separated from sesame grains It may consist of a mixture of sesame husks.

According to the present invention, the body portion is connected to the cover portion of the upper region in a closed state such that the cover portion of the upper region supplied with sesame is closed so that it can contact outside air through the upper region or contact less than a specified reference amount per unit time. It may include at least one of a closed state in which the end of the transfer pipe is closed so as to be in contact with outside air through the upper region via the transfer pipe without contact with the outside air or contact less than a specified reference amount per unit time.

According to the present invention, the input module may include an input network structure for forcibly inputting external air at a specified input pressure between the stored sesame seeds.

According to the present invention, the input network structure part is provided on one surface of the body part facing the suction module or spaced apart by a specified separation distance or more, and the input pressure part is between the sesame stored in the body part through the input network structure part. By homogeneously flowing outside air over a specified ratio, the temperature of the stored sesame can be uniformly and rapidly cooled to less than the specified carbonization temperature within a specified time.

According to the present invention, the input pressure unit may further include a function of homogeneously inhaling the stored ground air through the suction module at a specified ratio or more.

According to the present invention, the input module may further include a blocking structure for blocking contact between the empty space inside the body part that is not storing the sesame and the input network structure.

According to the present invention, the separation distance includes a distance for uniformly flowing at least a specified ratio between the sesame seeds stored in the body portion at a specified ratio or more before the external air introduced through the input module is sucked through the suction module. can be done by

According to the present invention, the input module further includes a tube structure that can be inserted or installed between the sesame seeds stored in the body portion, and the input network structure includes the entire surface of the tube structure forming the tube structure of the tube structure. It is formed in an area or a designated partial area, and the input pressure unit uniformly flows external air between the sesame stored in the body part through the tube structure part and the input network structure part at a specified ratio or more to control the temperature of the stored sesame for a specified time. It can be rapidly cooled homogeneously to below the specified carbonization temperature within.

According to the present invention, the input pressure unit may further include a function of homogeneously inhaling the stored ground air through the suction module at a specified ratio or more.

According to the present invention, the tube structure may include a straight tube structure.

According to the present invention, the tubular structure may include a tree-shaped tubular structure.

According to the present invention, the tube structure may include a tube structure in which a plurality of tubes having a specified geometric structure are arranged and connected in a previously designed geometric relationship.

According to the present invention, the tube structure is inserted or installed in the downward direction from the upper portion of the body portion to include a tube structure for introducing external air in the lower direction, or is inserted or installed in the upper direction from the lower portion of the body portion to the outside It may include a tube structure for introducing air in an upward direction.

According to the present invention, the tube structure may include a tube structure that is inserted or installed from one side of the body to the other side opposite to that to introduce external air in the direction of the other side.

According to the present invention, the input module may be able to inject external air into an empty space within the body when the suction module is provided with a suction network structure for sucking the ground air.

According to the present invention, the suction module may include a suction network structure for forcibly sucking the stored sesame air at a specified suction pressure.

According to the present invention, the suction network structure part is provided on one surface of the body part facing the input module or spaced apart by a specified separation distance or more, and the suction pressure part is, between the sesame seeds stored in the body part through the suction network structure part. By sucking air, the temperature of the stored sesame can be uniformly and rapidly cooled to less than the specified carbonization temperature within a specified time.

According to the present invention, the suction pressure unit may further include a function of uniformly flowing external air over a specified ratio between the sesame seeds stored in the body through the input module.

According to the present invention, the suction module may further include a blocking structure for blocking contact between the empty space inside the body portion that is not storing the sesame and the suction network structure.

According to the present invention, the separation distance includes a distance for uniformly flowing at least a specified ratio between the sesame seeds stored in the body portion at a specified ratio or more before the external air introduced through the input module is sucked through the suction module. can be done by

According to the present invention, the suction module further includes a pipe structure that can be inserted or installed between the sesame seeds stored in the body portion, and the suction network structure includes the entire surface of the tube structure forming the tube structure of the tube structure. It is formed in an area or a designated partial area, and the suction pressure unit sucks the air between the sesame seeds stored in the body through the tube structure and the suction network structure to reduce the temperature of the stored sesame to less than the specified carbonization temperature within a specified time. It can be rapidly cooled homogeneously.

According to the present invention, the suction pressure unit may further include a function of uniformly flowing external air over a specified ratio between the sesame seeds stored in the body through the input module.

According to the present invention, the tube structure may include a straight tube structure.

According to the present invention, the tubular structure may include a tree-shaped tubular structure.

According to the present invention, the tube structure may include a tube structure in which a plurality of tubes having a specified geometric structure are arranged and connected in a previously designed geometric relationship.

According to the present invention, the tubular structure includes a tubular structure that is inserted or installed from the upper part of the body in the lower direction to suck the stored ground air in the upper direction, or is inserted in the upper direction from the lower part of the body part Alternatively, it may include a tube structure that is installed and sucks the ground air in the storage in a downward direction.

According to the present invention, the tube structure may include a tube structure that is inserted or installed from one side of the body to the opposite side to suck the ground air in the storage in the direction of the one side.

According to the present invention, the suction module may be capable of sucking air in the empty space within the body portion when the input module is provided with an input network structure for introducing external air between the sesame seeds.

According to the present invention, the carbonization possible temperature is a temperature at which the carbonization reaction of the sesame hull is started or maintained, at least one of a temperature of 180 ° C. or higher, a temperature of 140 ° C. or higher for 1 minute or more, and a temperature of 110 ° C. This may include temperature.

According to the present invention, the low temperature below the carbonization possible temperature may be made including a temperature range of room temperature.

According to the present invention, by using the non-heated sesame storage device, there is an advantage that can prevent the sesame shell from being further carbonized while keeping the roasted sesame seeds through the stir-frying pot in an unheated state.

1 is a view showing the configuration of a non-heated sesame storage device according to an embodiment of the present invention.
Figure 2 is a view showing a process of processing the transferred sesame seeds in a non-heating state before supply to the storage device after being roasted through the stir-frying pot according to the embodiment of the present invention.

Hereinafter, the principle of operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the description to be given below relate to a preferred implementation method among various methods for effectively explaining the characteristics of the present invention, and the present invention is not limited only to the following drawings and description.

That is, the following embodiment corresponds to an embodiment of a preferred union type among numerous embodiments of the present invention, and an embodiment in which a specific configuration (or step) is omitted in the following embodiment, or a specific configuration (or step) An embodiment in which a function implemented in a function is divided into a specific configuration (or step), or an embodiment in which a function implemented in two or more configurations (or step) is integrated into any one configuration (or step), a specific configuration (or step) Embodiments in which the order of operation is replaced, etc. are clearly stated to be within the scope of the present invention, even if not separately mentioned in the following embodiments. Therefore, based on the following examples, it is clearly specified that various examples corresponding to a subset or a complement can be divided retroactively from the filing date of the present invention.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those of ordinary skill in the art to which the present invention belongs. only

1 is a view showing the configuration of a non-heated sesame storage device according to an embodiment of the present invention.

In more detail, the drawing 1 shows the temperature of the sesame in storage during storage before supplying the sesame transferred through the designated transfer system to the storage device after being roasted through the stir-frying pot. In order to rapidly cool from a high temperature higher than the possible temperature to a low temperature below the carbonization temperature within a specified time, external air is forced into the stored sesame at a specified input pressure, and the stored sesame air is forcibly sucked at a specified suction pressure. Thus, as showing the configuration of the non-heated sesame storage device 100 to prevent the sesame hull from being further carbonized even in an unheated state, those of ordinary skill in the art to which the present invention pertains, this figure 1 Various implementation methods for the non-heated sesame storage device 100 can be inferred by reference and/or modification, but the present invention includes all the inferred implementation methods, and the implementation method shown in FIG. 1 Only the technical characteristics are not limited.

Referring to Figure 1, the unheated sesame storage device 100 includes a body portion 105 for storing sesame seeds transported through a designated transport system in a non-heated state before being supplied to a storage device after being roasted in a stir-frying pot; Between the stored sesame in order to rapidly cool the temperature of the sesame stored in the body part 105 from a high temperature higher than the carbonization possible specified carbonization temperature of the sesame husk contained in the sesame to a low temperature lower than the carbonization temperature within a specified time An input module 110 for forcibly inputting external air to a specified input pressure, and an input pressure unit that generates a designated input pressure for forced input of external air through the input module 110 and provides the input module 110 to the input module 110 . In order to rapidly cool the temperature of the sesame stored in the 115 and the body portion 105 from a high temperature higher than the carbonization possible designated carbonization temperature of the sesame husk contained in the sesame to a low temperature less than the carbonization temperature within a specified time The suction module 120 for forcibly sucking the stored ground air at a specified suction pressure, and the suction module 120 by generating a specified suction pressure for forced suction of the ground air through the suction module 120 A suction pressure unit 125 provided to the, a discharge unit 130 for discharging the air between the stored sesame seeds to the outside based on the suction pressure and the input pressure, and a supply unit for supplying the cooled sesame seeds to the storage device ( 135) may be provided.

In the present invention, the sesame grains containing the sesame kernels and sesame hulls in their original state or separated from the sesame husks in less than a specified ratio, sesame kernels separated from the sesame grains by more than the specified ratio, and sesame seeds separated from sesame grains It may contain a mixture of shells.

According to the embodiment of the present invention, the body portion 105 may include a cover portion (not shown separately) for allowing the upper region to come into contact with the outside air, and the cover portion of the upper region supplied with the sesame seeds is closed to close the The end of the transfer pipe connected to the cover part of the upper region is closed in a closed state so that it is not in contact with the outside air through the upper region or is in contact with less than a specified reference amount per unit time, and through the upper region through the transfer pipe, the external air and The sealed state may include at least one of a non-contact state or a closed state capable of contacting less than a specified reference amount per unit time. Here, the reference amount designated per unit time may include a maximum amount that can be in contact with external air due to leakage.

The input module 110 may include an input network structure 140 for forcibly inputting external air at a specified input pressure between the stored sesame seeds. For example, the input module 110 may directly inject external air between the sesame seeds stored in the body portion 105 through the input network structure 140 .

According to the embodiment of the present invention, the input network structure unit 140 may be provided on one surface of the body portion 105 facing the suction module 120 or spaced apart by a specified separation distance or more, and the input pressure unit (115), the external air is uniformly flowed over the specified ratio between the sesame seeds stored in the body portion 105 through the input network structure unit 140 to lower the temperature of the stored sesame seeds within a specified time to less than the specified carbonization temperature. A homogeneous rapid cooling can be achieved.

The input pressure unit 115 may further include a function of homogeneously inhaling the stored ground air through the suction module 120 at a specified ratio or more. For example, it is possible to uniformly flow the external air between the sesame seeds by sucking the external air through the suction module 120 while pushing the external air through the input module 110 .

In addition, the input module 110 may further include a blocking structure 150 for blocking contact between the empty space inside the body portion 105 in which the sesame is not stored and the input network structure portion 140 . For example, it is possible to effectively inject external air through the sesame seeds only by blocking the external air from being introduced into the upper empty space of the body part 105 through the input network structure 140 using a blocking film. However, when the suction network structure part 155 and the blocking structure part 150 are included in the suction module 120, the external air flows between the sesame seeds in order to inhale it in a closed state even if the external air is injected into an empty space. The blocking structure 150 of the module 110 may be omitted.

According to the embodiment of the present invention, the separation distance is between the sesame seeds stored in the body portion 105 or more of the sesame seeds stored in the body portion 105 until the external air introduced through the input module 110 is sucked through the suction module 120. It is desirable to include a distance for homogeneous flow over a specified ratio.

According to the embodiment of the present invention, the input module 110 may further include a tube structure 145 that can be inserted or installed between the sesame seeds stored in the body portion 105 . In this case, the input network structure 140 is preferably formed in the entire area or a designated partial area of the tube structure surface forming the tube structure of the tube structure portion 145, and the input pressure portion 115 is the The external air is uniformly flowed over the specified ratio between the sesame stored in the body 110 through the tube structure 145 and the input network structure 140 to lower the temperature of the stored sesame to less than the specified carbonization temperature within the specified time. A homogeneous rapid cooling can be achieved.

Here, the input pressure unit 115 may further include a function of homogeneously inhaling the stored ground air through the suction module 120 at a specified ratio or more.

Meanwhile, the tube structure 145 may include any one or more of a straight tube structure, a tree tube structure, and a tube structure in which a plurality of tubes having a specified geometric structure are arranged and connected in a pre-designed geometric relationship.

In addition, the tube structure 145 is inserted or installed from the upper portion of the body portion 105 in the lower direction to include a tube structure for introducing the external air in the lower direction, or from the lower portion of the body portion 105 . It may include a tube structure that is inserted or installed in the upper direction to introduce external air in the upper direction.

In addition, the tube structure 135 may include a tube structure that is inserted or installed from one side of the body portion 105 to the other side opposite to that of the body portion 105 to introduce external air in the direction of the other side.

According to the implementation method of the present invention, when the input module 110 is provided with a suction network structure part 155 for sucking the ground air in the suction module 120, the empty space in the body part 105 is provided. External air can be introduced. For example, when the suction network structure part 155 and the blocking structure part 150 are provided in the suction module 120 , the input network structure part 140 and the blocking structure part 150 of the input module 110 are omitted and an empty space is provided. Even when external air is put into the , it is in a sealed state, so the external air injected into the empty space flows between the sesame seeds and can be sucked through the suction module 120 .

The suction module 120 may include a suction network structure 155 for forcibly sucking the stored ground air at a specified suction pressure, and the suction network structure 155 includes the input module 110 and It may be provided on one side of the body portion facing or spaced apart by a specified separation distance or more, and the suction pressure unit 125 sucks the ground air stored in the body portion 105 through the suction network structure portion 155. to allow the temperature of the stored sesame to be uniformly and rapidly cooled to less than the specified carbonization temperature within a specified time. In addition, the suction pressure unit 125 may include a function of uniformly flowing external air over a specified ratio between the sesame seeds stored in the body unit 105 through the input module 110 .

In addition, the suction module 120 may further include a blocking structure 150 for blocking contact between the empty space inside the body portion 105 that is not storing the sesame and the suction network structure portion 155 . For example, only when the air in the empty space above the body part 105 is blocked from being sucked through the suction network structure part 155 by using a blocking film, the crushed air can be effectively sucked. However, when the inputting module 110 includes the input network structure 140 and the blocking structure 150, even if the intake module 120 sucks air in the empty space, it sucks the ground air in the closed state. In this case, the blocking structure 150 of the suction module 120 may be omitted.

Here, the distance between the sesame seeds stored in the body part 105 and more than the specified ratio among the sesame seeds stored in the body part 105 before the external air introduced through the input module 110 is sucked through the suction module 120. It may include a distance to do it.

On the other hand, the suction module 120 may further include a pipe structure part 145 that can be inserted or installed between the sesame stored in the body part 105, and the suction network structure part 155 is the pipe structure part 145. ) may be formed on the entire area of the surface of the tube structure forming the tube structure of ) or on a designated partial area. At this time, the suction pressure unit 125 sucks the air between the sesame seeds stored in the body portion 105 through the pipe structure portion 145 and the suction network structure portion 155 to set the temperature of the stored sesame seeds within a specified time. It can be allowed to rapidly cool homogeneously below the carbonization temperature.

Here, it is preferable that the suction pressure unit 125 further includes a function of uniformly flowing outside air at a specified ratio or more between the sesame seeds stored in the body unit 105 through the input module 110 .

The tube structure 145 may include any one or more of a straight tube structure, a tree tube structure, and a tube structure in which a plurality of tubes having a specified geometric structure are arranged and connected in a pre-designed geometric relationship.

In addition, the tube structure portion 145 is inserted or installed from the upper portion of the body portion 105 in the lower direction to include a tube structure for sucking the stored ground air in the upper direction, or the body portion 105 It may include a tube structure that is inserted or installed in the upper direction from the bottom of the to suck the ground air in the storage in the lower direction.

In addition, the tube structure 145 may include a tube structure that is inserted or installed from one side of the body 105 to the opposite side to suck the ground air in the storage in the direction of the one side.

Here, the suction module 120 can suck the air in the empty space in the body part 105 when the input module 110 is provided with an input network structure 140 for introducing external air between the sesame seeds. have.

According to the implementation method of the present invention, the carbonization possible temperature is the temperature at which the carbonization reaction of the sesame hull is started or maintained, at least one of a temperature of 180 ℃ or more, a temperature of 140 ℃ or more for 1 minute or more, and a temperature of 110 ℃ or more for 5 minutes or more. It may contain one temperature.

According to the embodiment of the present invention, the low temperature less than the carbonization possible temperature may include a temperature range of room temperature. For example, normal room temperature is a temperature of about 25 (±5) ° C., and a low temperature less than the carbonization temperature is lower than the carbonization temperature, so that the carbonization reaction may stop, but it may be cooled to a room temperature range.

Figure 2 is a view showing a process of processing the transferred sesame seeds in a non-heating state before supplying to a storage device after being roasted through a stir-fry according to an embodiment of the present invention.

In more detail, FIG. 2 shows that the sesame seeds transported through the designated transport system after being roasted through the stir-fry pot in the non-heated sesame storage device 100 shown in FIG. 1 are stored before being supplied to the storage device, the storage being In order to rapidly cool the temperature of sesame seeds from a high temperature above the specified carbonization possible temperature of the sesame husk contained in the sesame seeds to a low temperature below the carbonization temperature within a specified time, external air is forced into the space between the stored sesame seeds at a specified input pressure, , the process of forcibly sucking the stored ground air at a specified suction pressure so that the sesame husk is no longer carbonized even in an unheated state, those of ordinary skill in the art to which the present invention pertains If so, various implementation methods for the above process (eg, an implementation method in which some steps are omitted or the order is changed) can be inferred by referring and/or modifying this figure 2, but the present invention provides for all implementations inferred above. It is made including a method, and the technical characteristics are not limited only to the implementation method shown in FIG. 2 .

Referring to Figure 2, the illustrated implementation method is from the process of storing sesame seeds transferred through a designated transfer system after being roasted through a stir-fry in the unheated sesame storage device 100 in an unheated state before being supplied to the storage device. may be initiated ( 200 ).

The unheated sesame storage device 100 is stored in order to rapidly cool the temperature of the sesame in storage from a high temperature higher than the carbonization possible specified carbonization temperature of the sesame shell contained in the sesame to a low temperature less than the carbonization temperature within a specified time. Creates an input pressure for forcibly inputting external air to a specified input pressure between the sesame seeds (205).

And, the unheated sesame storage device 100 rapidly cools the temperature of the sesame in storage from a high temperature above the specified carbonization possible temperature of the sesame husk contained in the sesame to a low temperature below the carbonization possible temperature within a specified time. In order to generate a suction pressure for forcibly sucking the specified suction pressure of the stored ground air for the purpose (210).

Thereafter, the unheated sesame storage device 100 forcibly injects external air to a specified input pressure based on the suction pressure and input pressure, and discharges the stored sesame air to the outside so that the sesame is rapidly cooled ( 215).

And, the unheated sesame storage device 100 supplies the cooled sesame seeds to the storage device (220).

100: non-heated sesame storage device 105: body part
110: input module 115: input pressure unit
120: suction module 125: suction pressure part
130: discharge unit 135: supply unit
140: input net structure 145: pipe structure
150: blocking structure 155: suction net structure

Claims (31)

In a device for storing sesame seeds transferred through a designated transport system after being roasted through a stir-frying pot before supplying them to a storage device,
a body portion for storing the transferred sesame seeds in an unheated state after being roasted to a specified completion temperature through the stir-frying pot;
In order to rapidly cool the temperature of the sesame stored in the body from a high temperature above the specified carbonization possible temperature of the sesame hull contained in the sesame to a low temperature below the carbonization temperature within a specified time, external air is passed between the stored sesame seeds. an input module for forcibly inputting a specified input pressure;
an input pressure unit generating a specified input pressure for forcibly inputting external air through the input module and providing it to the input module;
The air between the stored sesame seeds is designated to rapidly cool the temperature of the sesame stored in the body from a high temperature above the specified carbonization possible temperature of the sesame husk contained in the sesame to a low temperature below the carbonization temperature within a specified time. a suction module for forced suction by suction pressure;
a suction pressure unit for generating a specified suction pressure for forcibly sucking the ground air through the suction module and providing it to the suction module; and
A discharge unit for discharging the air between the sesame seeds stored in the storage based on the suction pressure and the input pressure; and
A non-heated sesame storage device for preventing carbonization using air intake and input before storage, including a supply unit for supplying the cooled sesame seeds to the storage device.
According to claim 1, wherein the breaking,
Sesame grains containing sesame grains and sesame hulls in their original state or separated by less than a specified ratio of sesame husks;
Sesame kernels separated from the sesame kernels by a specified ratio or more,
An unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it contains a mixture of sesame husks separated from sesame grains.
According to claim 1, wherein the body portion,
A state in which the cover of the upper region supplied with sesame is closed so that it can be contacted without contact with outside air through the upper region or in contact with less than a specified standard amount per unit time;
At least one of a closed state in which the end of the transfer pipe connected to the cover part of the upper region is closed to be in contact with outside air through the upper region via the transfer pipe or in contact with less than a specified reference amount per unit time Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes.
According to claim 3, wherein the input module,
Non-heated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it comprises an input network structure for forcibly inputting external air at a specified input pressure between the stored sesame seeds.
5. The method of claim 4,
The input network structure part is provided on one surface of the body part facing the suction module or spaced apart by a specified separation distance or more,
The input pressure unit homogeneously flows external air between the sesame seeds stored in the body portion through the input network structure portion at a specified ratio or more to uniformly rapidly cool the temperature of the stored sesame seeds to less than the specified carbonization temperature within a specified time. Unheated sesame storage device to prevent carbonization using air intake and input before storage.
The method of claim 5, wherein the input pressure unit,
Non-heated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it further comprises a function of homogeneously inhaling the ground air in the storage through the suction module at a specified ratio or more.
The method of claim 4, wherein the input module,
Unheated sesame storage for preventing carbonization using air intake and input before storage, characterized in that it further comprises a blocking structure that blocks contact between the empty space inside the body part that is not storing the sesame and the input network structure Device.
The method of claim 7, wherein the separation distance,
Air before storage, characterized in that it comprises a distance for homogeneously flowing at least a specified ratio between sesame seeds stored in the body portion or more among sesame seeds stored in the body until external air introduced through the input module is sucked through the suction module Unheated sesame storage device to prevent carbonization using suction and input.
5. The method of claim 4,
The input module further comprises a tube structure that can be inserted or installed between the sesame stored in the body portion,
The input network structure portion is formed in the entire area or a designated partial area of the tube structure surface forming the tube structure of the tube structure portion,
The input pressure unit homogeneously flows outside air between the sesame stored in the body part through the tube structure part and the input network structure part at a specified ratio or more to uniformly reduce the temperature of the stored sesame seeds to less than the specified carbonization temperature within a specified time. An unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that cooling.
The method of claim 9, wherein the input pressure unit,
Non-heated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it further comprises a function of homogeneously inhaling the ground air in the storage through the suction module at a specified ratio or more.
10. The method of claim 9, wherein the tubular structure,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a straight tube structure.
10. The method of claim 9, wherein the tubular structure,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a tree-shaped tube structure.
10. The method of claim 9, wherein the tubular structure,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a tube structure in which a plurality of tubes having a specified geometric structure are arranged and connected in a previously designed geometric relationship.
14. The method according to any one of claims 9 to 13, wherein the tubular structure comprises:
It is inserted or installed from the upper part of the body in the lower direction to include a tube structure for introducing external air in the lower direction, or
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it is inserted or installed from the lower part of the body in the upper direction to include a tube structure for introducing external air in the upper direction.
14. The method according to any one of claims 9 to 13, wherein the tubular structure comprises:
Non-heated sesame seeds for preventing carbonization using air intake and input before storage, characterized in that it is inserted or installed from one side of the body to the opposite side and includes a tube structure for introducing external air in the other side direction. storage device.
The method of claim 13, wherein the input module,
Non-heated sesame seeds for preventing carbonization using air intake and input before storage, characterized in that when the suction module is provided with a suction network structure for sucking the ground air, external air can be introduced into the empty space in the body. storage device.
The method of claim 3, wherein the suction module,
Non-heated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a suction network structure for forcibly sucking the stored ground air at a specified suction pressure.
18. The method of claim 17,
The suction network structure part is provided on one surface of the body part facing the input module or spaced apart by a specified separation distance or more,
The suction pressure unit, the air before storage, characterized in that by sucking the ground air stored in the body portion through the suction network structure, and uniformly rapidly cooling the temperature of the stored sesame to less than the specified carbonization temperature within a specified time. Unheated sesame storage device to prevent carbonization using suction and input.
The method of claim 18, wherein the suction pressure unit,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it further comprises a function of uniformly flowing external air over a specified ratio between the sesame seeds stored in the body through the input module. .
The method of claim 17, wherein the suction module,
Storage of unheated sesame seeds for preventing carbonization using air intake and input before storage, characterized in that it further comprises a blocking structure that blocks contact between the empty space inside the body that is not storing the sesame and the suction network structure Device.
The method of claim 20, wherein the separation distance,
Air before storage, characterized in that it comprises a distance for homogeneously flowing at least a specified ratio between sesame seeds stored in the body portion or more among sesame seeds stored in the body until external air introduced through the input module is sucked through the suction module Unheated sesame storage device to prevent carbonization using suction and input.
18. The method of claim 17,
The suction module further comprises a tube structure that can be inserted or installed between the sesame stored in the body portion,
The suction network structure portion is formed in the entire area or a designated partial area of the tube structure surface forming the tube structure of the tube structure portion,
The suction pressure unit sucks the air between the sesame seeds stored in the body through the tube structure and the suction network structure to uniformly and rapidly cool the temperature of the stored sesame to less than the specified carbonization temperature within a specified time. Unheated sesame storage device to prevent carbonization using air intake and input before storage.
The method of claim 22, wherein the suction pressure unit,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it further comprises a function of uniformly flowing external air over a specified ratio between the sesame seeds stored in the body through the input module. .
23. The method of claim 22, wherein the tubular structure,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a straight tube structure.
23. The method of claim 22, wherein the tubular structure,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a tree-shaped tube structure.
23. The method of claim 22, wherein the tubular structure,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a tube structure in which a plurality of tubes having a specified geometric structure are arranged and connected in a previously designed geometric relationship.
27. The method of any one of claims 22 to 26, wherein the tubular structure comprises:
It is inserted or installed from the upper part of the body part to the lower direction and includes a tube structure for sucking the stored ground air in the upper direction, or
Storage of unheated sesame seeds for preventing carbonization using air intake and input before storage, characterized in that it is inserted or installed in the upper direction from the lower part of the body portion and includes a tube structure for sucking the stored ground air in the lower direction Device.
27. The method of any one of claims 22 to 26, wherein the tubular structure comprises:
Carbonization prevention using air suction and input before storage, characterized in that it includes a tube structure inserted or installed from one side of the body to the opposite side to suck the ground air in storage in the direction of the one side For unheated sesame storage device.
The method of claim 26, wherein the suction module,
Non-heated sesame seeds for preventing carbonization using air intake and input before storage, characterized in that when the input module is provided with an input network structure for introducing external air between the sesame seeds, the air in the empty space in the body can be inhaled. storage device.
According to claim 1, wherein the carbonization possible temperature,
As the temperature at which the carbonization reaction of the sesame husk is initiated or maintained,
temperature above 180℃,
1 minute or more at a temperature of 140°C or higher;
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it comprises at least one temperature of 5 minutes or more at a temperature of 110 ° C. or higher.
According to claim 1, wherein the low temperature less than the carbonization possible temperature,
Unheated sesame storage device for preventing carbonization using air intake and input before storage, characterized in that it includes a temperature range of room temperature.?

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