KR101653764B1 - Box package for drone - Google Patents

Abstract

The present invention relates to a box package for storing an object of a low temperature, used for a drone. The present invention is to provide a box package for storing an object of a low temperature, used for a drone, capable of absorbing impact so that outer impact is not transferred to an object of a low temperature. The box package includes: a main body housing having an inner space with an open upper part by comprising a first lower surface and second side surfaces extended from the first lower surface to the upper side, wherein a connection module connected to the drone is installed on the outer side of a pair of the second side surfaces facing each other among the second side surfaces; an impact absorbing member absorbing the impact in order for the outer impact not to be transferred to the object of the low temperature, by being inserted into the inner space of the main body housing while a part of the one or more objects of the low temperature is inserted and assembled; and a shielding cover shielding the upper part of the main body housing as a lower part is combined by being compulsorily fitted into the inner space when being inserted into the inner space, wherein a refrigerant member maintaining the inner space at the low temperature required by the object of the low temperature is inserted and connected in a sliding method.

Description

Box package for drone} < / RTI >

The present invention relates to a box package for storing a low temperature object used in a drone, and more particularly, to a box package for storing a low temperature object which is required to be kept at low temperature so as not to move or shake, To a box package for storing a low temperature object used in an absorbable drones.

The drones began to be developed for military use in the United States and have been used for reconnaissance / surveillance and combat. Recently, however, the scope of application of drones for industrial and civilian use is rapidly expanding. Currently, there is a wide range of applications such as broadcast shooting, recreation, agriculture, communication relay, disaster information collection for pollution and natural disaster area, And is being developed in various forms to be applicable to these fields.

IT companies such as Amazon, Google, and Facebook are using unmanned aerial vehicles to revolutionize existing infrastructure such as logistics and communications networks. Amazon is striving to build a multi-copter shipping service. In the Matternet, we are promoting the continental-wide drones business, which overcame the operational limitations of small UAVs through multiple UAV relays, It is also known that it will be used for delivering medical goods to areas where access is not easy.

In this way, it is as important as a drone to be a transportation box package that transports logistics for a logistics delivery service using an unmanned aircraft such as a drone. As mentioned above, logistics delivery service using unmanned airplane is expected to be most used for delivery service for delivering low-temperature objects requiring low temperature such as medical goods. It is most important to keep the low temperature constantly for a low temperature object, It is also important to protect low temperature objects from impact.

Particularly, in the case of transporting the logistics using the unmanned airplane, when the transportation to the dangerous area is required, the unmanned airplane generally drops the transportation package storing the low temperature object from the ground without landing or landing. However, at this time, the low-temperature object is damaged or damaged due to the drop impact. Therefore, it is important to realize a transportation package that can maintain the low-temperature maintenance for a certain period of time for freshness of the low-temperature object, absorb the external impact, and prevent damage and breakage of the low-temperature object.

Korean Patent Publication No. 10-2016-0020454

The object of the present invention is to provide a box package for storing a low temperature object which can be fixedly stored so that a low temperature object requiring low temperature keeping is not moved or shaken and is used in a dron capable of absorbing impact so that external impact is not transmitted to a low temperature object The purpose.

The present invention relates to a box package for storing a low temperature object, which is transported by a drone and requires low temperature maintenance, the box package comprising: a first lower surface and an inner surface having a second upper surface extending from the first lower surface, And a coupling module that is connected to the drones is installed outside the pair of mutually facing second side surfaces of the second side surfaces. A shock absorbing member which is inserted into the internal space of the main body housing in a state where one or two or more of the low temperature objects are assembled with each other so as to absorb the impact so that an impact from the outside is not transmitted to the low temperature object; And a refrigerant member for holding the internal space at a low temperature required by the low temperature object is inserted and coupled in a sliding manner, and when the lower portion is inserted into the internal space, the refrigerant is inserted into the internal space in an interference fit manner, A low temperature object storage box package used in a dron including a shielding cover for shielding a low temperature object.

The box package for storing a low temperature object used in the drone according to the present invention has the following effects.

First, since the refrigerant member is slidably inserted into the portion of the shielding cover which is inserted into the internal space of the main body housing, the internal space of the main body housing can be maintained at a temperature required by the low temperature object.

Secondly, since the lower surface of the cover portion is in close contact with the upper ends of the first side surfaces of the main body housing, heat loss of the internal space of the main body housing can be prevented by inserting the main body housing into the internal space of the main body housing.

Thirdly, not only the low temperature object is fitted to the shock absorbing member but also the fixing groove is formed in the refrigerant coupling portion of the shield cover to insert the low temperature object, so that the low temperature object can be prevented from moving or shaking in the internal space of the main body housing.

1 is an exploded perspective view showing a box package for storing a low temperature object used in a drone according to an embodiment of the present invention.
2 is a perspective view showing a shielding cover of a box package for storing a low temperature object used in a drone according to an embodiment of the present invention.
3 and 4 are sectional views illustrating the structure of a box package for storing a low temperature object used in a drone according to an embodiment of the present invention.

1 to 4 show a box package for storing a low temperature object used in the drones according to the present invention.

Referring to FIGS. 1 to 4, a box package 1000 for storing a low temperature object used in a dron according to an embodiment of the present invention includes a box package 1000 for storing a low temperature object used in the dron, 300, an impact absorbing member 400, and a shielding cover 100. Prior to a specific description of an embodiment of the present invention, the low temperature object 10 is illustratively a pharmaceutical product.

The main body housing 300 includes a first side surface 310 and a first side surface 310. The first side surface 310 extends from the first bottom surface of the main body housing 300. The main body housing 300 includes a first side surface 310, (350). As shown in FIG. 2, the main body housing 300 is generally formed in a rectangular parallelepiped shape, but it is not limited thereto and may be formed in various shapes. In the present embodiment, the first front side 310, the first rear side 320, the first right side 330, and the second rear side 330 extend upward from the first lower surface (unrepresented) The body housing 300 is formed in a rectangular parallelepiped shape in which an upper portion is opened and an inner space 350 is formed to include the left side surface 340.

The main body housing 300 is formed of synthetic resin. The synthetic resin used to form the main body housing 300 includes any one of expanded polypropylene (EPP) and expanded polystyrene (EPS). The foamed polypropylene has an advantage of being excellent in cracking resistance, flexibility and chemical resistance. Expanded polystyrene is made by expanding polystyrene by the action of a foaming agent, and is lightweight, and has advantages of excellent water resistance, heat insulation, soundproofness, and cushioning properties. Since the main body housing 300 is formed of such a material, even if the main body housing 300 is impacted from the outside, the impact is transmitted to the low temperature object 10 stored in the internal space 350 of the main body housing 300 Can be prevented. Particularly, the box package for storing a low-temperature object used in the dron according to the present embodiment is applied to a logistics delivery system using an unmanned airplane such as a drone, and is used for storing a low temperature object The main body housing can prevent the impact generated at this time from being transmitted to the low temperature object.

On the other hand, a coupling module 301 is installed on the outer side of the main body housing 300 so as to connect the low temperature object storage box package 1000 used for the drone to a drone (not shown). 1, the coupling module 301 includes the first right side surface 330 and the second left side surface 330 facing each other among the first side surfaces 310, 320, 330, and 340 of the main body housing 300, Is installed on the surface (340). In this embodiment, the coupling module 301 is applied in the form of a bar as shown in FIG. 1, but it is not limited thereto and may be formed in various shapes that can be connected to the drone (not shown) .

The impact absorbing member 400 is inserted into the internal space 350 of the main body housing 300 so that a shock from the outside is transmitted to the low temperature object 10, The shock is absorbed.

The shock absorbing member 400 includes a second upper surface 410 spaced apart from a second lower surface and a second upper surface 410 spaced apart from the second lower surface by a predetermined height, (Not shown). In this embodiment, the second sides 420 and 430 include a second front side 420, a second rear side (not shown), a second right side 430, and a second left side (not shown).

With this structure, in the present embodiment, the shock absorbing member 400 is formed in the form of a rectangular parallelepiped as shown in FIG. Although the shock absorbing member 400 is generally formed in the form of a rectangular parallelepiped, it is not limited thereto and may be formed in various shapes. Since the shock absorbing member 400 is inserted into the internal space 350 of the main body housing 300, the shape of the shock absorbing member 400 should be the same as that of the main body housing 300.

The shock absorbing member 400 is assembled by inserting a part of the low temperature object 10 as described above. Therefore, the shock absorbing member 400 is formed with an insertion groove 401 into which a part of the low temperature object 10 can be inserted and assembled. One or a plurality of the low temperature objects 10 stored in the low temperature object storage box package 1000 used for the drone may be used. In the present embodiment, a plurality of the low temperature objects 10 are stored.

Accordingly, a plurality of insertion grooves 401 are formed in the shock absorbing member 400 so that the low temperature objects 10 can be inserted and assembled. The number of the insertion grooves 401 to be formed is not limited, and may be variously changed according to the manufacturing environment. The insertion groove 401 is recessed by a predetermined depth in the direction from the second upper surface 410 toward the second lower surface. On the other hand, the low temperature object 10 is not completely inserted into the insertion groove 401, and only a part of the low temperature object 10 is inserted into the insertion groove 401. At this time, the low temperature object 10 is inserted into the insertion groove 401 in an interference fit manner. Accordingly, as shown in FIGS. 1, 3, and 4, an upper portion of the low temperature object 10 protrudes upward from the impact absorbing member 400. Therefore, the low temperature object 10 is prevented from flowing or shaking in the insertion groove 401.

As described above, since the main body housing 300 is formed of a synthetic resin excellent in cracking and buffering properties, it is possible to prevent the impact transmitted from the outside by the main body housing 300 from being transmitted to the low temperature object 10 can do. However, the impact transmitted to the low-temperature object 10 can not be completely blocked only by preventing the impact by the main body housing 300. Therefore, when the impact from the outside is primarily blocked in the main body housing 300, the impact absorbing member 400 absorbs the impact not blocked by the main body housing 300 and is transmitted to the low temperature object 10 Thereby preventing secondary damage.

The shock absorbing member 400 is formed of porous rubber or porous synthetic resin. That is, the shock absorbing member 400 is formed of rubber or synthetic resin sponge. The rubber or synthetic resin has elasticity and has the effect of absorbing or reflecting the impact transmitted from the outside. In particular, as described above, since the rubber or synthetic resin sponge is in a porous form, the effect of absorbing impact is further improved. Therefore, an external impact which is not primarily blocked by the main body housing 300 is absorbed by the impact absorbing member 400 and is not transmitted to the low temperature object 10. Accordingly, the low temperature object 10 can be protected more safely from external impacts.

The shielding cover 100 is slidably coupled to a refrigerant member 30 capable of keeping the internal space 350 of the main body housing 300 at a low temperature required by the low temperature object 10. [ A lower portion of the shielding cover 100 is inserted into the inner space 350 of the main body housing 300 and inserted into the main body housing 350 to shield the upper portion of the main body housing 300.

2, the shield cover 100 includes a cover 110, a partition wall 113, and a coolant coupler 130. The cover 110 includes a cover 130, The cover portion 110 is formed in the form of a flat plate. In this embodiment, as shown in FIG. 2, the cross section is formed in the form of a flat plate having a rectangular shape, but not limited thereto, and may be formed in various shapes. However, it is generally formed in a shape corresponding to the outer shape of the main body housing 300. The cover 110 may include a lower surface 111 that is spaced apart from the first side 310, 320, 330, 340 of the body housing 300 when the shielding cover 100 is engaged with the body housing 300. [ (311, 321, 331, 341). In this way, the cover 110 is in close contact with the main body housing 300, thereby preventing heat loss in the internal space 350 of the main body housing 300.

The partition wall portion 113 extends from a lower surface of the cover portion 110 and is formed integrally with the cover portion 110. [ The partition wall portion 113 is formed such that the size of a virtual cross-section by the partition wall portion 113 is smaller than the size of the cross section of the cover portion 110. [ The partition wall portion 113 is formed to extend downward from the lower surface 111 of the cover portion 110 so as to form a groove in the center thereof. The partition 130 is inserted into the main body housing 300 in an interference fit manner. A portion of the refrigerant member 30, which will be described later, is inserted into the groove portion (not illustrated) formed by the partition wall portion 113.

The main body housing 300 is provided with a mold fitting portion 360 inside the first side faces 310, 320, 330 and 340 so as to be concave downward from the upper ends of the first side faces 310, 320, 330, Respectively. When the partition wall 113 is inserted into the main body housing 300 in a detent manner, the partition wall 113 is formed with the mold cavity 360. Particularly, the partition 113 has a protrusion 113a protruding from the outer surface and extending along the circumferential direction of the partition 113, and the protrusion 113 The engaging groove 361 is formed so as to extend along the circumferential direction of the mold part 360 so as to engage with the mold part 113a.

That is, when the partition wall portion 113 is inserted into the main body housing 300 in an interference fit manner, the partition wall portion 113 is formed with the mold cavity portion 360, It is possible to prevent the shielding cover 100 from being detached from the main body housing 300 while being caught by the groove 361. Although the fixing force of the shielding cover 100 and the main body housing 300 is further improved by the protrusion 113a and the latching groove 361 as described above in the present embodiment, The same structure as the retaining groove 113a and the retaining groove 361 may be omitted.

The cover 110 is formed of a synthetic resin including any one of expanded polypropylene (EPP) and expanded polystyrene (EPS) like the main housing 300. In addition, since the partition wall 113 is integrally formed with the cover 110, the partition wall 113 is formed of a synthetic resin containing any one of expanded polypropylene (EPP) and expanded polystyrene (EPS). Accordingly, the cover 110 and the partition wall 113 primarily block the external impact that can be electrolyzed on the upper portion of the low-temperature object storage box package 1000 used in the drone.

A part of the refrigerant coupler 130 is inserted into the groove portion formed by the partition wall portion 113 and fixed to the lower surface 111 of the cover portion 110. The remaining part of the refrigerant coupling part 130 is inserted into the internal space 350 of the main body housing 300 so that the cross section of the refrigerant coupling part 130 is formed in the same shape as the cross section of the internal space 350 do. The coolant coupling part 130 is separately formed from the cover part 110 and is fixed by adhesion. Accordingly, the coolant coupling unit 130 may be manufactured in various manners, and may be modified according to the shape of the low temperature object 10 and fixed to the lower surface of the cover unit 110.

 When the shielding cover 100 is engaged with the main housing 300, the remaining portion of the coolant coupling part 130, which is not inserted into the groove, Is inserted into the space 350.

In the refrigerant connection part 130, the refrigerant member 30 is slidably coupled. Accordingly, a coolant coupling groove 130b is formed on one side of the coolant coupling part 130 so as to extend in the longitudinal direction or the width direction, and the coolant member 30 can be coupled in a sliding manner.

The refrigerant member 30 includes a sponge impregnated with PCM particles (not shown). The PCM particles (not shown) are frozen to maintain the internal space 350 of the main body housing 300 at a temperature required by the low temperature object 10. The sponge impregnated with the PCM particles (not shown) not only protects the PCM particles (not shown), but also protects the PCM particles The temperature of the object 10 can be reduced. Meanwhile, in the present embodiment, as described above, the refrigerant member 30 includes the sponge that encloses the PCM particles (not shown). However, the present invention is not limited thereto and various refrigerant members may be used.

1 and 2, the refrigerant coupling groove 130b, to which the refrigerant member 30 is coupled in a sliding manner, is connected to the right side (not shown) of the refrigerant coupling part 130, (130). However, the present invention is not limited thereto, and may be extended along the width direction of the refrigerant coupling part 130 on the front side (unrepresented) or the rear side (unrepresented) of the refrigerant coupling part 130.

The lower surface 131 of the coolant coupling part 130 is formed with a fixing groove 130a through which the low temperature object 10 is inserted to fix the low temperature object 10. As described above, since a plurality of the low-temperature objects 10 are stored in the present embodiment, a plurality of the fixing grooves 130a are also formed. The positions of the fixing grooves 130a are aligned with the positions of the insertion grooves 401 in the same direction. The size of the cross section of each of the fixing grooves 130a may be equal to or greater than the cross sectional area of the portion of the low temperature object 10 inserted into the fixing groove 130a.

As described above, since the low temperature object 10 inserted into the shock absorbing member 400 is inserted into the insertion groove 401, only a part of the low temperature object 10 is inserted into the insertion groove 401, (See FIGS. 1, 3, and 4). [0053]

When the refrigerant coupling part 130 is inserted into the internal space 350 when the shielding cover 100 is coupled to the main body housing 200 and the fixing groove 130a of the refrigerant coupling part 130 is inserted, And the protruding portion of the low temperature object 10 is inserted and fixed. Therefore, since the low temperature object 10 is fixed not only by the insertion groove 401 but also by the fixing groove 130a, it can be more stably fixed.

Like the shock absorbing member 400, the refrigerant coupling unit 130 is formed of a rubber or synthetic resin sponge. As described above, the impact transmitted from the outside is primarily blocked by the cover 110 and the partition wall 113, but all the external impact is transmitted to the cover 110 and the partition wall 113 ). ≪ / RTI > Therefore, an impact not blocked by the cover 110 and the partition 113 can be transmitted to the low temperature object 10. However, if the refrigerant coupling unit 130 is formed of rubber or synthetic resin sponge, the shock absorbing unit can absorb shocks that are not blocked by the cover unit 110 and the partition 130, 10 can be more safely protected.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1000: Box package for low temperature object storage for drone
100: Shielding cover
110: cover part 113: partition wall part
113a:
130:
130a: Fixing groove 130b: Refrigerant coupling groove
300: main body housing 350: inner space
360: Mold fitting 361:
400: shock absorbing member 401: insertion groove
10: low temperature object 30: refrigerant

Claims (7)

1. A box package for storing a low temperature object, which is transported by a drone and requires low temperature maintenance,
A first side surface and a first side surface extending upwardly from the first bottom surface to form an inner space having an upper portion opened, and a pair of outer side surfaces of the first side surfaces facing each other A main body housing having a coupling module connected to the drone;
Temperature object is inserted and inserted into the internal space of the main body housing in a state in which a part of one or more of the low-temperature objects is assembled, thereby absorbing the impact so that an impact from the outside is not transmitted to the low-temperature object, Absorbing member; And
A refrigerant member for holding the internal space at a low temperature required by the low-temperature object is inserted and coupled in a sliding manner, and when a lower portion is inserted into the internal space, the refrigerant is inserted into the internal space in an interference fit manner, And a shielding cover for shielding the light-
The shield cover
A cover portion formed in a flat plate shape and having a bottom surface in close contact with an upper end of the first side surfaces when the shielding cover is engaged with the main body housing;
A partition wall portion extending downward from a lower surface of the cover portion so as to form a groove portion in the center and integrally formed with the cover portion, the partition wall being inserted and coupled to the interior of the main body housing in an interference fit manner; And
The refrigerant is inserted into the groove portion and fixed to the lower surface of the cover portion, the remaining portion is inserted into the internal space, and the refrigerant is inserted into the refrigerant coupling portion And a refrigerant coupling part formed by a synthetic resin sponge,
And a fixing groove for fixing the low temperature object is formed by inserting the remaining portion of the low temperature object into the lower surface of the refrigerant coupling portion,
Wherein the coolant member is used for a dron which is formed of a sponge impregnated with PCM particles. delete The method according to claim 1,
The main body housing,
Wherein the first and second side surfaces are recessed in a downward direction from an upper end of the first side surfaces to form a mold-engaging portion formed with the partition wall portion. The method of claim 3,
In the partition wall portion,
Protrusions protruding from the outer side surface and extending along the circumferential direction of the partition wall portion are formed,
Wherein the inner side surface of the molded part is formed with an engaging groove extending along the circumferential direction of the molded part so as to engage with the protrusion. delete The method according to claim 1,
Wherein the shock absorbing member comprises:
A second lower surface spaced upward from the second lower surface by a predetermined height and second side surfaces connecting the second lower surface and the second upper surface,
Wherein an insertion groove is formed in the second upper surface to be recessed by a predetermined depth toward the second lower surface to insert a part of the low temperature object,
Wherein the fixing groove and the insertion groove are formed in a dron in which respective central axes thereof are coaxially aligned. delete

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