KR20140117943A - Apparatus for drying agricultural products using using far infrared rays - Google Patents

Abstract

Disclosed is an agricultural product drying apparatus using far infrared rays. The agricultural product drying apparatus using far infrared rays in the present invention comprises: a housing provided to allow a worker access thereto; a drying chamber provided in the housing, and installed at regular intervals separately from the upper part and side part of the housing in order to form a circulation passage of dry air between the drying chamber and the housing, wherein an opening part connected to the circulation passage is formed on one side of the drying chamber; a heating unit installed in the circulation passage to be arranged on the upper part of the drying chamber, and provided to radiate high-temperature far infrared rays and form dry air; an air blowing part installed on the other side of the drying chamber, and provided to send the dry air formed by the heating unit to the drying chamber in order to continuously circulate the dry air in one side direction in the housing; and a dehumidifying part installed on the surface of the housing to be connected to the circulation passage, and provided to remove moisture contained in the dry air which is circulated along the circulation passage. The agricultural product drying apparatus using far infrared rays further comprises: an ascending air current blowing part installed on the inner wall of the housing close to the opening part of the drying chamber, and provided to form the ascending current of the dry air which has passed through the drying chamber; and an auxiliary heating unit installed on the inner wall of the housing to be arranged above the ascending air current blowing part, and provided to firstly heat the dry air which has passed through the drying chamber before reheating the dry air by the heating unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus for drying far-

More particularly, the present invention relates to a device for drying far-infrared agricultural produce, and more particularly to a device for drying far-infrared dry air in a direction of one side of a drying chamber from inside of a housing during drying of various agricultural products such as red pepper, radish, The present invention relates to a drying apparatus for far-infrared agricultural products which can be dried.

Generally, agricultural products are harvested for long-term storage purposes, dried, and shipped. These agricultural products include red pepper, radish, dried herbs, shiitake mushrooms, and ginseng.

In order to dry the agricultural products, in the past, natural drying was used by simply using sunlight and wind, but it takes a very long time to dry naturally, so productivity is low, a large space is required, and dust or various foreign substances The quality of the product is deteriorated and it can not be carried out on rainy or humid days and there are disadvantages that it is troublesome and inconvenient because the producers must dry the agricultural products that are dried frequently from time to time.

Therefore, recently, a forced drying apparatus capable of artificially forcibly drying agricultural products is mainly used.

The apparatus for drying agricultural produce is provided with a drying chamber which is hermetically sealed inside, and the agricultural products to be dried are put into the drying chamber by using a harvester or the like, and then the heat source is exothermically operated to generate high heat, So that hot air flows. That is, the agricultural product drying apparatus is to dry agricultural products by direct heat by a heat source and flow of hot air by a blowing fan.

As a heat source provided in the agricultural product drying apparatus, a burner for generating heat in accordance with the combustion of fuel and an electric heater for generating heat in accordance with the supply of electricity are mainly used.

Among them, the electric heater is widely adopted because it is convenient to use because it is unnecessary to supplement fuel when only electricity is supplied, and it is possible to maintain cleanliness around the electric heater.

However, the conventional agricultural product drying apparatus and the agricultural product drying method using the same have the following problems.

That is, the agricultural products are dried using the hot air and the hot air, which means that the surface of the agricultural products exposed to the hot heat is dried, and the inside is hardly dried.

As a result, corruption frequently occurs inside the agricultural products after drying, resulting in degraded quality.

In addition, since the heat can not penetrate into the inside of the agricultural product, the drying speed is somewhat slow, so that the drying time is long, the productivity is low, the energy consumption is large according to the operation for a long time, There is a problem that the quality of agricultural products is deteriorated due to discoloration, discoloration and deterioration of components.

Therefore, at present, there is a need for an agricultural product drying apparatus capable of uniformly and rapidly drying not only the surface but also the inside of the agricultural product.

In addition, as an example of agricultural products, pepper is used as an example.

Dried red pepper is naturally dried in sunlight, and sunflower is highly popular in the market because it is completely dried and sold at a high price.

However, since sunflower is produced through natural drying, the same problems as described above due to natural drying occur.

On the other hand, pepper can be mechanically dried using a drying device. According to mechanical drying, a product having a significantly lowered taste and nutritive value than that of a sunflower is produced, resulting in lower consumer's preference and price.

Therefore, there is a demand for research and development on an agricultural product drying apparatus which can increase the commerciality of agricultural products and dry them quickly without damaging the taste.

The patent documents related to the present invention are as follows. Korean Registered Patent No. 10-0881867 (entitled "Grain Dryer", Registered Jan. 29, 2009) Korean Registered Patent No. 10-1137774 (entitled "Rotary Drum Type Agricultural Product Dryer ", Registered April 12, 2012)

The present invention has been made in view of the above problems, and it is an object of the present invention to provide a drying method and a drying method for drying various kinds of agricultural products by drying far infrared ray drying air in one direction of a drying chamber inside a housing, Infrared agricultural produce drying apparatus capable of minimizing the occurrence of noise by buffering a collision between dry air and the inner wall of the housing by an ascending air flow.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the particular embodiments that are described. It will be apparent to those skilled in the art, There will be.

According to an aspect of the present invention, there is provided a portable terminal comprising: a housing provided to allow an operator to enter and exit; And an opening formed in the housing so as to be spaced apart from an upper portion and a side portion of the housing so as to form a circulation passage of dry air between the housing and the housing and having an opening connected to the circulation passage at one side thereof Drying room; A heating unit installed on the circulation passage so as to be disposed at an upper portion of the drying chamber and configured to radiate high-temperature far-infrared rays and to form dry air; A blowing unit installed on the other side of the drying chamber and capable of circulating the drying air formed by the heating unit to the drying chamber and continuously circulating in the one direction inside the housing; And a dehumidifying part connected to the circulation passage on the surface of the housing and adapted to remove moisture contained in the dry air circulating along the circulation passage, wherein the dehumidifying part is disposed on the inner wall of the housing adjacent to the opening part of the drying chamber A rising airflow blowing unit installed to generate a rising air stream of the drying air passing through the drying chamber; And an auxiliary heating unit installed on an inner wall of the housing so as to be disposed on the upper portion of the upward airflow blowing unit and heating the dry air passing through the drying chamber before being reheated by the heating unit, Is achieved by an agricultural product drying apparatus.

The upward airflow blowing unit is formed of a plurality of blowing fans arranged at a predetermined distance from each other along the inner wall of the housing.

And the auxiliary heating unit is formed to have a smaller power capacity than the heating unit.

Wherein the heating unit comprises: a plurality of heater bodies installed at upper portions of the drying chamber so as to be spaced from each other at a predetermined interval in a direction perpendicular to the circulating direction of the drying air; And a plurality of nano carbon tube heaters spaced apart from each other by a predetermined distance in the lateral direction so as to mount both ends of the heater body and generating heat to form dry air according to supply of power.

The nano carbon tube heater includes: a plurality of CNT tubes mounted on the heater body; And a heating wire embedded in the CNT tube and generating heat according to supply of power.

The CNT tube has an insulator coupled to an inner side of both ends and slidable to be compressed and restored by the elastic member on the outer side of the CNT tube, And the nano carbon tube heater is detachably mounted on the heater body.

The CNT tube has guide protrusions protruding from the surface at both ends thereof. The guide protrusion is inserted into the insulator so that the CNT tube can be compressed and restored, And a guide groove is formed to be engaged.

According to the present invention, it is possible to quickly dry the various agricultural products by circulating the far infrared ray drying air in one direction of the drying chamber in the inside of the housing, and to perform rapid drying by the rising airflow blowing portion forming the rising air flow inside the housing It is possible to increase the circulation speed of the dry air and also to minimize the noise by buffering the collision between the dry air and the inner wall of the housing.

Further, the present invention provides an auxiliary heating unit that can be roughly heated before the drying air passed through the opening of the drying chamber is heated by the heating unit, so that the power and time And the drying time of the laundry stored in the drying chamber can be remarkably shortened by rapid heating of the drying air by the heating unit.

1 is a perspective view of a far-infrared agricultural produce drying apparatus according to an embodiment of the present invention.
2 is a front view of the inside of the far infrared agricultural produce drying apparatus shown in FIG.
FIG. 3 is a plan view of the inside of the far-infrared agricultural produce drying apparatus shown in FIG. 1. FIG.
FIG. 4 is a cross-sectional view of the inside of the far-infrared agricultural produce drying apparatus shown in FIG. 1 viewed from another angle.
5 is an enlarged cross-sectional view showing the inside of the portion "A" in Fig.
FIG. 6 is a cross-sectional view schematically illustrating the flow of dry air inside the far-infrared agricultural produce drying apparatus according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions will not be described in order to simplify the gist of the present invention.

FIG. 1 is a perspective view of a far-infrared agricultural produce drying apparatus according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the inside of a far-infrared agricultural produce drying apparatus shown in FIG. 1, 4 is a cross-sectional view of the inside of the far-infrared agricultural produce drying apparatus shown in Fig. 1 viewed from another angle, Fig. 5 is an enlarged view of the "A" And FIG. 6 is a cross-sectional view schematically illustrating the flow of dry air inside the far-infrared agricultural produce drying apparatus according to an embodiment of the present invention.

1 to 3, the far-infrared agricultural produce drying apparatus according to an embodiment of the present invention includes a housing 100, a drying chamber 110 installed inside the housing 100, a housing 100, A blowing unit 130 for continuously circulating dry air from the heating unit 120 in the direction of one side of the drying chamber 110 inside the housing 100, a heating unit 120 for forming far infrared ray drying air inside the drying chamber 110, A rising airflow blowing part 140 for forming a rising airflow of the drying air that has passed through the drying room 110 and a circulation process of dry air blown back to the heating unit 120 by the upward airflow blowing part 140 And a dehumidifying unit 160 for discharging moisture contained in the drying air circulating inside the housing 100 to the outside of the housing 100. [ ).

1, the housing 100 has a structure for forming a main frame of a far-infrared agricultural produce drying apparatus according to an embodiment of the present invention. In addition to being able to enter and leave the worker, An access structure of at least one door 102 is provided so that the dryable matter receiving portion 114 in a state in which the tray 116 is mounted can be taken in and out.

A person skilled in the art will be able to enter and leave the inside space of the drying chamber 110 and the inside space of the drying chamber 110 Various structures that can be closed can be considered.

The drying chamber 110 is provided inside the housing 100 as shown in FIG. The drying chamber 110 is spaced apart from the upper and the side portions of the housing 100 by a predetermined distance so as to form a circulation passage 110A of the drying air between the drying chamber 110 and the housing 100.

One side of the drying chamber 110 is provided with an opening 112 which is opened so that the dry air introduced into the drying chamber 110 can be discharged to the circulation passage 110A. That is, the open portion 112 provides a space through which the dry air is introduced into the drying chamber 110 by the blowing portion 140 and can be quickly discharged to the circulation passage 110A.

The drying air blown into the drying chamber 110 is continuously circulated in the direction of one side of the drying chamber 110 from inside the housing 100 by forming the opening 112 at one side of the drying chamber 110.

That is, the dry air is introduced into the drying chamber 110 by the blow-in unit 130 and then can be quickly discharged to the circulation passage 110A through the opening 112, thereby enabling continuous circulation of the dry air .

In the drying chamber 110, a plurality of trays 116 on which the respective objects to be dried are placed are vertically stacked with respect to each other. To this end, an object to be dried 114 having a structure in which a plurality of trays 116 are accommodated is provided. At this time, the plurality of tongues 116 is detachably coupled to the laundry receiver 114.

That is, the dry storage unit 114 has a structure in which a plurality of trays 116 are vertically stacked in a multi-stage manner.

2 to 4, the heating unit 120 is provided on the circulation passage 110A to radiate high-temperature far-infrared rays and form dry air. The heating unit 120 is installed on the circulation passage 110A so as to be disposed on both sides of the upper portion of the drying chamber 110 with respect to the opening 112 provided in the drying chamber 110, And a plurality of nano carbon tube heaters 124 mounted on the heater body 122.

The plurality of heater main bodies 122 are arranged to mount a plurality of nano carbon tube heaters 124 and are arranged at a predetermined interval in a direction orthogonal to the circulating direction of the drying air at the upper portion of the drying chamber 110 . A plurality of receiving grooves 123 capable of detachably mounting both ends of the nano carbon tube heater 124 are formed on the mutually facing surfaces of the heater body 122. At this time, the receiving grooves 123 are spaced apart from one another in the up, down, left, and right directions.

A plurality of nano carbon tube heaters 124 are constructed to generate dry air having a far infrared ray and a plurality of CNT tubes 125 having heating wires 126 embedded in the receiving grooves 123 of the heater body 122 And is mounted in the lateral direction. At this time, the heating wire 126 is formed of nano carbon fiber which generates heat according to the supply of power and generates far-infrared rays.

At both ends of each CNT tube 125, an elastic member 128, for example an insulator 127 predominating in force externally expanding by a spring, is mounted on the CNT tube 125, And the insulator 127 is coupled to the receiving groove 123 of the heater body 122 so as to be partially or entirely received.

That is, when insulators 127 mounted on both ends of each CNT tube 125 are compressed inward to each other, when they reach the receiving groove 123 formed in the heater body 122, Each CNT tube 125 can be easily mounted.

A guide protrusion 125A protruding from the surface is formed at both ends of the CNT tube 125. A guide groove 127A is formed in the insulator 127 so that the guide protrusion 125A can be inserted into the guide groove 127A, . At this time, the guide groove 127A is formed to have a constant length so as to guide the compression of the insulator 127 to the CNT tube 125 and the restoration of the home position. The insulator 127 can be compressed and retracted at both ends of the CNT tube 125 according to the structure of the guide protrusion 125A and the guide groove 127A, .

Dismantling of the CNT tube 125 from the heater main body 122 follows the reverse order of the above procedure.

By adopting such a structure that the CNT tube 125 can be easily mounted and disassembled, the CNT tube 125 which is not working can be easily replaced.

Reference numeral 129, which is not described in the heating unit 120 of the present embodiment, indicates a power supply line for supplying power to the heating wire 126 embedded in the CNT tube 125.

Such a nano carbon tube heater 124 greatly reduces the drying time from about 37 to 40 hours by a general electric heater to 20 to 25 hours, and is excellent in energy saving effect. At this time, the wavelength band of the nano carbon tube heater 124 should preferably be set to a frequency between 3 and 20 micrometers to provide far-infrared emissivity and radiant energy having optimum conditions for drying the agricultural product, It is possible to provide excellent antimicrobial activity by excluding the possibility of damaging agricultural products.

The heating unit 120 serves to heat the drying air discharged through the opening 112 provided in the drying chamber 110.

As shown in FIGS. 2 to 4, the blowing unit 130 is configured to continuously circulate the drying air in one direction of the drying chamber 110 from inside the housing 100. To this end, the discharge portion 130 is installed on the other side of the drying chamber 110 corresponding to the opening portion 112.

The blowing unit 130 of this embodiment is composed of nine blowing fans installed on the other side of the drying chamber 110. The number of the blowing fans can be variously changed according to the volume of the drying chamber 110. [

The airflow 130 flows into the interior of the drying chamber 110 by the drying air formed by the heating unit 120 and flows into the drying chamber 110 through the interior of the housing 100 110 in the direction of one side.

As shown in FIGS. 2 and 3, the rising airflow blowing unit 140 is installed on the inner wall of the housing 100 adjacent to the opening 112 of the drying chamber 110. At this time, the upward airflow blowing parts 140 are formed as a plurality of blowing fans arranged at predetermined intervals along the inner wall of the housing 100.

The upward airflow blowing portion 140 forms a rising air flow of the drying air inside the housing 100 so that the drying air circulating through the drying chamber 110 can be increased by the upward flow, 110 so as not to hit the inner wall of the housing 100, thereby minimizing the noise generated during the collision between the inner wall of the housing 100 and the dry air.

For example, when dry air is introduced into the drying chamber 100 by the blowing unit 130 without the rising airflow blowing unit 140, the dry air passing through the opening 112 of the drying chamber 110 Collides with the inner wall of the housing 100 due to the blowing speed of the blowing part 130, and severe noise is generated due to such a collision.

Thus, the upward airflow blowing portion 140 forms an upward flow so that the dry air passing through the opening portion 112 of the drying chamber 110 inside the housing 100 does not collide with the inner wall of the housing 100, It is possible to minimize the generation of noise by buffering the collision of the dry air with the inner wall of the housing 100.

As shown in FIGS. 2 and 3, the auxiliary heating unit 150 is configured such that dry air having passed through the drying chamber 110 is heated before being heated by the heating unit 120. That is, the auxiliary heating unit 150 is installed on the inner wall of the housing 100 so as to be disposed on the upper portion of the upward airflow blowing unit 140. At this time, the auxiliary heating unit 150 is provided with a plurality of auxiliary heating units 150 spaced apart from one another along the inner wall of the housing 100.

The auxiliary heating unit 150 is formed to have a smaller electric power capacity than the heating unit 120 and serves to heat the drying air passing through the drying chamber 110 before the heating unit 120 reheats the drying air. Accordingly, the dry air passing through the drying chamber 110 is heated by the auxiliary heating unit 150, thereby reducing power and time generated when the drying air is heated to a predetermined temperature by the heating unit 120, The drying time of the laundry stored in the drying chamber 110 can be remarkably shortened.

Here, the configuration of the auxiliary heating unit 150 is the same as that of the heating unit 120 described above, and thus a detailed description thereof will be omitted.

As shown in FIG. 1, the dehumidifying unit 160 is configured to remove moisture contained in the dry air, and is installed at an upper portion of the front surface of the housing 100. At this time, the dehumidifying unit 160 is provided with a dehumidifier that opens and closes to remove moisture contained in the dry air.

In this embodiment, the dehumidifying part 160 is installed on the upper part of the front surface of the housing 100 so as to remove the moisture contained in the drying air. However, the installation position of the dehumidifying part 160, And may be installed at various positions on the outer surface of the body 100.

The dehumidifying part 160 serves to remove moisture contained in the drying air circulating along the circulation passage 110A.

That is, the dehumidifying part 160 removes the moisture contained in the drying air circulating along the circulation passage 110A so that only the intact dry air from which moisture has been removed is introduced into the drying chamber 110, .

The dehumidifying unit 160 is operated to open and close under the control of a control unit (not shown) provided in the housing 100 to remove moisture contained in the drying air.

Hereinafter, the operation of the far-infrared agricultural produce drying apparatus according to one embodiment of the present invention will be described with reference to FIG.

As shown in FIG. 6, in order to dry an object to be dried such as agricultural products by the far-infrared agricultural produce drying apparatus of the present embodiment, the object to be dried is first stored in the drying chamber 110.

When power is supplied to the far-infrared agricultural produce drying apparatus in the above-described state, the heating unit 120 provided on the circulation passage 110A is heated to emit high-temperature far-infrared rays and at the same time, air in the housing 100 is dried It starts to be converted. At the same time, the dry air generated by the heating unit 120 is blown into the inside of the drying chamber 110 due to the operation of the air blowing unit 130, and the open air of the drying chamber 110 A rising airflow is formed on the circulation passage 110A adjacent to the circulation passage 110A.

That is, when the upward airflow is formed by the upward airflow blowing part 140, the dry air passing through the opening part 112 of the drying chamber 110 is increased by the upward airflow and is rapidly blown toward the heating unit 120 At the same time, the collision between the inner wall of the housing 100 and the dry air can be buffered, so that the noise generated when the dry air passing through the opening portion 112 of the drying chamber 110 hits the inner wall of the housing 100 can be minimized .

The drying air generated by the heating unit 120 flows into the interior of the drying chamber 110 while maintaining a constant flow in the circulation passage 110A according to the operation of the blowing unit 130, The dry air having passed through the dried material is discharged through the open portion 112 and then circulated along the circulation passage 110A in a state of being increased by the upward flow of the upward airflow blowing portion 140, And is continuously circulated in the direction of one side of the drying chamber 110 inside the housing 100 so as to be reheated and then introduced into the drying chamber 110 again.

At this time, the drying air having passed through the opening portion 112 of the drying chamber 110 is raised by the upward airflow blowing portion 140, passes through the auxiliary heating unit 150 before being heated by the heating unit 120, . As a result, the drying air is heated by the auxiliary heating unit 150, so that the power and time generated when the drying air is heated to the predetermined temperature by the heating unit 120 can be reduced and the heating air can be quickly heated So that the drying air can be blown into the drying chamber 110.

According to the circulation structure of the dry air, the dried article stored in the drying chamber 110 can be dried quickly.

As described above, the far-infrared agricultural produce drying apparatus according to an embodiment of the present invention can rapidly dry the far-infrared drying air circulating in the direction of one side of the drying chamber 110 from inside the housing 100, The circulation speed of the drying air can be increased by the rising airflow blowing part 140 forming the rising airflow inside the housing 100 so that the drying air can be rapidly dried and the airflow between the drying air and the inner wall of the housing 100 is buffered Noise can be minimized.

The present invention also provides an auxiliary heating unit 150 that can be roughly heated before the drying air that has passed through the opening 112 of the drying chamber 110 is heated by the heating unit 120, The drying time of the laundry stored in the drying chamber 110 can be remarkably shortened by the rapid heating of the drying air by the heating unit 120 can do.

In addition, since the bacterial fungus is wiped off when the agricultural products are dried by the far-infrared ray effect radiated from the heating unit 120 and the auxiliary heating unit 150, freshness and circulation period of the agricultural products after drying are prolonged, It is possible to provide a far superior effect than the agricultural products produced by the dryer.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, such modifications or variations should not be individually understood from the technical spirit and viewpoint of the present invention, and modified embodiments should be included in the claims of the present invention.

100: housing 110: drying chamber
110A: circulation passage 112:
120: heating unit 130:
140: ascending air flow-rich portion 150: auxiliary heating unit
160: Dehumidification part

Claims (7)

A housing provided so that an operator can enter and exit the housing;
And an opening formed in the housing so as to be spaced apart from an upper portion and a side portion of the housing so as to form a circulation passage of dry air between the housing and the housing, Drying room;
A heating unit installed on the circulation passage so as to be disposed at an upper portion of the drying chamber and configured to radiate high-temperature far-infrared rays and to form dry air;
A blowing unit installed on the other side of the drying chamber and capable of circulating the drying air formed by the heating unit to the drying chamber and continuously circulating in the one direction inside the housing; And
And a dehumidifying part connected to the circulation passage on the surface of the housing and adapted to remove moisture contained in the circulating drying air along the circulation passage,
A rising airflow blowing unit installed on an inner wall of the housing adjacent to the opening of the drying chamber and configured to form a rising air stream of the drying air passing through the drying chamber; And
And an auxiliary heating unit installed on an inner wall of the housing so as to be disposed on an upper portion of the upward airflow blowing unit and heating the dry air passing through the drying chamber to be roughly heated before reheating by the heating unit. Drying device. The method according to claim 1,
Wherein the upward air flow blowing unit is formed by a plurality of blowing fans disposed at a predetermined interval from each other along the inner wall of the housing. The method according to claim 1,
Wherein the auxiliary heating unit is formed to have a smaller electric power capacity than the heating unit. The method according to claim 1,
The heating unit includes:
A plurality of heater bodies disposed at upper portions of the drying chamber so as to be spaced apart from each other in a direction orthogonal to the circulating direction of the drying air; And
And a plurality of nano carbon tube heaters arranged to be spaced apart from each other at a predetermined interval in the lateral direction so as to mount both ends of the heater body and to generate dry air according to supply of power, . 5. The method of claim 4,
In the nano carbon tube heater,
A plurality of CNT tubes mounted on the heater body; And
And a heating wire built in the CNT tube and generating heat according to supply of power. 6. The method of claim 5,
In the CNT tube,
Wherein an elastic member is coupled to the inside of both ends and an insulator slidingly coupled to the outside to be compressed and restored by the elastic member is coupled,
In the heater body,
Receiving grooves are formed on the surfaces of the insulators facing each other so as to accommodate part or all of the insulators,
Wherein the nano carbon tube heater is detachably mounted on the heater body. The method according to claim 6,
In the CNT tube,
Guide projections projecting from the surface are formed at both ends,
In the insulator,
Wherein the CNT tube is formed with a guide groove in which the guide protrusion is inserted to slide and guide the CNT tube so that the CNT tube can be compressed and restored and restrained so as to be prevented from being detached.

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