KR102423908B1 - Ascon Insulation Box - Google Patents

Abstract

The present invention relates to an ascon insulation box. More specifically, the present invention relates to an ascon insulation box which is able to accommodate ascon released from an ascon manufacturing apparatus, and keep the temperature of ascon uniform until the ascon is transferred and discharged to a road construction site. As such, according to the present invention, the ascon insulation box comprises: an outer box (10) with an opened upper side; an inner box (20) placed in the outer box (10), formed in a smaller size than that of the outer box (10), and having an opened upper side; a cover (30) formed to cover an upper side of the outer box (10) and the inner box (20); a plurality of fixing apparatuses (50) installed between the outer box (10) and the inner box (20), fixing the outer box (10) on an outer side of the inner box (20), and forming a gap space between the outer box (10) and the inner box (20); a plurality of fixing brackets (40) formed on an outer surface of the inner box (20); a plurality of fixing bars (42) inserted into and engaged with the plurality of fixing brackets (40) and fastened with one side of the plurality of fixing apparatuses (50); a high-temperature insulator (60) filling the gap space between the outer box (10) and the inner box (20); and a moisture preventive agent coated on an inner surface of the outer box (10), an outer surface of the inner box (20), the plurality of fixing brackets (40), and the plurality of fixing bars (42). As each of the plurality of fixing apparatuses (50) is fixed on the plurality of fixing bars (42), one side of the plurality of fixing apparatuses (50) is prevented from coming in contact with an outer surface of the inner box (20).

Description

Ascon Insulation Box {Ascon Insulation Box}

The present invention relates to an asphalt concrete insulation box, and more particularly, to an asphalt concrete insulation box that accommodates asphalt concrete shipped from an asphalt concrete manufacturing device, transports the asphalt concrete to a road construction site, and allows the asphalt concrete to be maintained at a constant temperature until it is discharged. it's about

Asphalt concrete (hereinafter 'ascon') generally used for pavement of roads is a black solid or semi-solid material whose main component is hydrocarbon, and a solid component called asphaltene is dispersed in an oily component called martin.

Such asphalt concrete is used for road pavement and airport pavement according to its type, or is used for waterproofing in pavement or construction fields.

In particular, asphalt mainly used for road pavement or airport pavement is mixed with aggregates such as sand, stone dust, crushed stone, and gravel, which is called asphalt concrete.

These asphalt concrete can be transported from the manufacturing plant to the road construction site by a separate asphalt concrete storage device that can be transported while maintaining the temperature of the asphalt concrete in order to maintain the quality of the asphalt concrete.

As a portable asphalt concrete storage device capable of storing asphalt in this way, Republic of Korea Registered Utility Model No. 20-0454650 (removable asphalt concrete storage device, hereinafter “prior art”) is disclosed.

The prior art includes a heater unit installed on one side of the loading unit; a flow path extending from the heater unit and communicating with the receiving unit; a blower for supplying the heat generated by the heater to the accommodating part through the flow path; an asphalt concrete discharge unit for discharging the asphalt concrete in the accommodating part through a discharge port formed on the lower side of the loading part; a first sensor for sensing the temperature of the asphalt concrete in the receiving unit; a second sensor provided at the end of the outlet to sense the temperature of the asphalt cone discharged through the outlet; and a control unit that compares the detection values of the first and second sensors, compensates for the difference, and controls the heater unit to generate additional heat for maintaining the temperature of the discharged asphalt concrete at a preset temperature. A portable asphalt concrete storage device that can be easily transported to the construction site while maintaining the asphalt concrete at a constant temperature, and can maintain the discharged asphalt concrete temperature at an appropriate temperature for construction even if the received asphalt concrete is discharged for construction. Its purpose is to provide

However, the prior art has a structure in which a flow path is formed in the loading part for accommodating the asphalt concrete to supply heat generated through the heater part to the flow path, so the structure of the loading part is very complicated, and in order to keep the temperature of the asphalt concrete There is a problem in that the heater unit must be continuously operated.

In addition, even when heat is supplied to the asphalt concrete in the accommodating part through the heater, heat is transmitted only to the outer part of the accommodating part and not sufficiently transferred to the inside. There is a problem in that it is difficult to maintain an appropriate temperature.

In addition, even if heat transfer to the asphalt concrete through the heater part is well done, if too much heat is transferred in the receiving part and the temperature of the asphalt concrete becomes above the appropriate temperature, the temperature of the asphalt concrete discharged to the asphalt concrete discharge part is too high, so the AP flows down from the aggregate and is detached There are problems that can cause

Therefore, in the asphalt concrete storage device for storing and transporting asphalt, there is a need to develop an asphalt concrete insulation box that can store and transport asphalt while maintaining the temperature of asphalt concrete at an appropriate temperature from an asphalt concrete manufacturing plant to a road construction site even with a simple structure. to be.

Republic of Korea Registered Utility Model Publication No. 20-0454650 (2011.07.19. Announcement)

The present invention has been devised to solve the above problems, between the outer box and the inner box, and between the outer box and the inner box and between the upper plate and the lower plate of the cover to form a spaced space for providing a high-temperature insulation material and a heat insulation board, and The fixing device that secures the upper and lower plates of the cover to each other prevents direct contact with the inner box and upper plate of the cover, thereby preventing the heat of the inner box and lower plate of the cover from being conducted to the upper plate of the outer box and cover, An object of the present invention is to provide an asphalt concrete insulation box that blocks the heat of asphalt concrete loaded inside the insulation box from being conducted and released to the outside.

In addition, by applying a desiccant to the space between the outer box and the inner box and between the upper plate and the lower plate of the cover, the temperature difference occurs in the space formed between the outer box and the inner box and between the upper plate and the lower plate of the cover. An object of the present invention is to provide an asphalt concrete insulation box that blocks the heat of asphalt concrete loaded inside the inner box from being conducted to the outside through the moisture.

In order to achieve the above-described problem to be solved, the asphalt concrete insulation box of the present invention is an asphalt concrete insulation box that accommodates asphalt and maintains an appropriate temperature of asphalt concrete, the outer box 10 with an open upper side, the outer box ( 10) provided on the inside of the inner box 20, which is formed in a size smaller than that of the outer box 10 and has an open upper side, a cover formed to cover the upper side of the outer box 10 and the inner box 20 30), is installed between the outer box 10 and the inner box 20 to fix the outer box 10 to the outside of the inner box 20, and the outer box 10 and the inner box 20 A plurality of fixing devices 50 to form a spaced space therebetween, a plurality of fixing brackets 40 formed on the outer surface of the inner box 20, the plurality of fixing brackets 40 are fitted and coupled to the plurality of fixing brackets 40 A plurality of fixing bars 42 to which one side of the fixing device 50 is fastened, a high-temperature insulating material 60 filled in a space between the outer box 10 and the inner box 20, and the outer box 10 and a desiccant applied to the inner surface, the outer surface of the inner box 20, the plurality of fixing brackets 40 and the plurality of fixing bars 42, and the plurality of fixing devices 50 are the plurality of fixing bars. By being respectively fixed to 42, one side of the plurality of fixing devices 50 is blocked from contacting the outer surface of the inner box 20, and between the outer box 10 and the inner box 20 by the desiccant. It is characterized in that it prevents the generation of moisture due to the temperature difference between the outside air and asphalt concrete in the formed space.

In addition, the cover 30 includes an upper plate 31 and a lower plate 33, and a plurality of fixing devices 50' are installed between the upper plate 31 and the lower plate 33, so that a spaced space is formed. is formed, the spaced space is filled with a high-temperature insulating material 60 , a plurality of fixing brackets 40 ′ are formed on the inner surface of the upper plate 31 , and the plurality of fixing brackets 40 ′ are provided with the plurality of fixing brackets 40 ′. A plurality of fixing bars 42' to which one side of the fixing device 50' is fastened are fitted, and the plurality of fixing devices 50' are respectively fixed to the plurality of fixing bars 42' by being fixed to the plurality of fixing bars 42'. One side of the fixing device 50 is cut off from contact with the inner surface of the upper plate 31 of the cover 30 , the inner surface of the cover 30 , the plurality of fixing brackets 40 ′, and the plurality of fixing bars (42') is characterized in that the desiccant is applied.

In addition, the fixing bar (42, 42') is characterized in that it is formed of wood or MC nylon.

In addition, the upper side of the space between the outer box 10 and the inner box 20 is characterized in that the insulation resin 70 is provided and finished.

In addition, the cover 30 is characterized in that the insulating resin 70 is provided on the lower side of the lower plate 33, or the lower plate 33 is formed of the insulating resin (70).

In addition, the lower edge of the lower edge of the insulating resin 70 provided on the lower side of the cover 30 or the lower edge of the lower plate 33 of the cover 30 formed of the insulating resin 70 that the packing material 71 is provided characterized.

In addition, the inner surface of the outer box 10 and the upper surface of the lower plate 33 of the cover 30 is characterized in that the insulation board 80 is provided.

In addition, at the lower side of one side of the outer box 10 and the lower side of the inner box 20 one side, an outlet 100 communicating the outer box 10 and the inner box 20 is formed, and the outlet ( On the upper side of 100), the opening and closing door 110 for opening and closing the outlet 100 is formed rotatably by a hinge, and the opening and closing door 110 is characterized in that opening and closing is controlled by the opening and closing cylinder 112.

In addition, it is characterized in that the heat insulating resin (70) is provided around the inner surface of the opening and closing door (110) in contact with the outlet (100).

In addition, the insulating resin 70 is characterized in that it is formed of a bakelite plate or MC nylon plate.

In addition, it is characterized in that the packing material (71) is provided at the edge of the insulating resin (70) provided around the inner surface of the opening and closing door (110).

In addition, a screw 200 is formed rotatably in the longitudinal direction toward the outlet 100 in the inner lower central portion of the inner box 20 , and the inner box 20 is rotated by the rotation of the screw 200 . It is characterized in that the asphalt concrete loaded in the outlet 100 is moved in the direction.

In addition, the opening/closing door 110 is characterized in that an auxiliary outlet and an auxiliary opening/closing door 120 having a size smaller than the size of the opening/closing door 110 are formed.

In addition, a support plate 300 for supporting the outer box 10 is provided on the lower side of the outer box 10 , and a lifting member 400 is provided between the outer box 10 and the support plate 300 . ) is characterized in that it is provided.

In addition, the desiccant is prepared by adding 1 to 10 parts by weight of styrene-butadiene-styrene (SBS) to 100 parts by weight of insulating oil to obtain a first mixture by heating and stirring, and an asphalt compound based on 100 parts by weight of the first mixture. compound) adding 30 to 70 parts by weight and heating and stirring to obtain a second mixture, adding 1 to 5 parts by weight of polyaniline (PANI) with respect to 100 parts by weight of the second mixture and heating and stirring to obtain a third mixture; A step of adding 6 to 12 parts by weight of zeolite to 100 parts by weight of the third mixture and heating and stirring to obtain a fourth mixture, 1 to 5 parts by weight of polybutene and 1 to 5 parts by weight of polybutene with respect to 100 parts by weight of the fourth mixture Adding 0.2 to 0.8 parts by weight of methyl methacrylate (PMMA) and stirring to obtain a fifth mixture by natural cooling, adding 30 to 70 parts by weight of xylene with respect to 100 parts by weight of the fifth mixture, It is characterized in that it is prepared through the step of obtaining a sixth mixture by adding and dissolving 10 to 40 parts by weight of solvent No. 3 with respect to 100 parts by weight of mixture 5.

The present invention according to the above configuration is between the outer box and the inner box and between the outer box and the inner box and between the upper plate and the lower plate of the cover and between the outer box and the inner box and the upper plate of the cover while forming a spaced space for providing the high-temperature insulation material and the insulation board between the upper plate and the lower plate Prevents the fixing devices between the lower plates from coming into direct contact with the upper plate of the inner box and cover, preventing the heat from the lower plate of the inner box and cover from being conducted to the upper plate of the outer box and cover, and loading it inside the asphalt insulation box By blocking the heat of the asphalt concrete from being conducted and released to the outside, it is possible to transfer the asphalt concrete from the asphalt concrete manufacturing plant to the road construction site while maintaining the proper temperature without having a heater part to heat the asphalt concrete in the insulation box. there is

In addition, by applying a desiccant to the space between the outer box and the inner box and between the upper plate and the lower plate of the cover, the temperature difference occurs in the space formed between the outer box and the inner box and between the upper plate and the lower plate of the cover. By blocking the conduction of the heat of asphalt concrete loaded inside the inner box to the outside through the moisture, there is an effect that the asphalt concrete loaded inside the asphalt concrete insulation box can be transported while maintaining it at an appropriate temperature for a long time.

1 is a perspective view showing the overall appearance of the asphalt concrete insulation box according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view illustrating a state in which FIG. 1 is viewed from the front.
FIG. 3 is a cross-sectional view illustrating a state in which FIG. 1 is viewed from the side.
Figure 4 is a cross-sectional view showing a view from the front of the asphalt concrete insulation box installed with a screw inside according to an embodiment of the present invention.
FIG. 5 is a cross-sectional view illustrating a state in which FIG. 4 is viewed from the side.
6 is a front view showing a state in which the support plate and the elevating member are coupled to the lower side of the outer box.
7 is a side view showing a state in which the support plate and the elevating member are coupled to the lower side of the outer box.
Figure 8 is a side view showing a state in which the asphalt concrete insulation box of the present invention is loaded on a truck.
9 is a side view showing a state that the asphalt concrete insulation box loaded on the truck is raised by the lifting member.
Figure 10 is a side view showing a state in which the asphalt concrete insulation box installed with the screw of the present invention is loaded on a truck.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and detailed description will be given. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

When an element is referred to as being “connected” or “connected” to another element, it is understood that it may be directly connected or connected to the other element, but other elements may exist in between. it should be

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, the technical idea of the present invention will be described in more detail with reference to the accompanying drawings. Since the accompanying drawings are merely examples shown to explain the technical idea of the present invention in more detail, the technical idea of the present invention is not limited to the form of the accompanying drawings.

Hereinafter, an asphalt concrete insulation box according to an example of the present invention will be described in detail with reference to FIGS. 1 to 7 .

1 is a perspective view showing the overall appearance of the asphalt concrete insulation box according to an embodiment of the present invention.

Referring to Figure 1, the asphalt concrete insulation box according to an example of the present invention can accommodate asphalt concrete shipped from the asphalt concrete manufacturing device, and transport the asphalt concrete to a road construction site so that the asphalt concrete can be maintained at a constant temperature until it is discharged. .

In addition, the outer box 10 and the inner box 20 are spaced apart by a plurality of fixing bars 42 and a fixing device 50 formed between the outer box 10 and the inner box 20, and the outer box ( 10) After applying a desiccant to the space formed between the inner box 20 and the inner box 20, by filling the high-temperature insulating material 60, the temperature of the asphalt concrete contained in the inner box 20 is prevented from lowering. It is possible to keep the asphalt contained in 1) at an appropriate temperature.

In addition, an insulating resin 70 is provided on each of the upper side of the spaced space between the outer box 10 and the inner box 20 and the lower side of the cover 30 so that the outer box 10 and the inner box 20 are connected to the cover 30 ) to prevent direct contact with the outer box 10 and the inner box 20 to block heat conduction that may occur due to direct contact with the cover 30, thereby maintaining the asphalt concrete at an appropriate temperature.

This asphalt concrete insulation box (1) is an outer box (10), an inner box (20), a cover (30), a fixing device (50), a fixing bracket (40), a fixing bar (42), a high temperature insulation material (60), heat insulation resin 70, and a desiccant.

Hereinafter, with reference to Figs. 1 to 7, the components of the asphalt concrete insulation box according to an example of the present invention will be described in detail.

The outer box 10 is a box-shaped frame formed on the outermost side of the asphalt concrete insulation box (1). The outer box 10 may be formed to have an open top. Accordingly, the inner box 20 to be described later may be formed to be located inside the outer box 10 .

The outer box 10 may be formed using a steel material such as a steel plate.

An inner box 20 may be provided inside the outer box 10 . The inner box 20 is formed in a size smaller than the size of the outer box 10 , and may be formed of the same material as the outer box 10 .

Therefore, since the inner box 20 is formed in a size smaller than the size of the outer box 10, the outer box 10 can be easily installed inside the inner box 20, and a fixing bar 42 and When the outer box 10 and the inner box 20 are integrated by the fixing device 50 , a spaced space is formed between the outer box 10 and the inner box 20 .

At this time, a plurality of fixing bars 42 having little thermal conductivity are provided on the outside of the inner box 20 so that one side of the plurality of fixing devices 50 does not come into contact with the outside of the inner box 20, and a plurality of fixing bars ( By fastening one side of the plurality of fixing devices 50 to 42 , the heat of the inner box 20 may not be directly conducted to the outer box 10 .

In addition, a high-temperature insulating material 60, a desiccant, an insulating board 80, etc. are further provided in the space between the outer box 10 and the inner box 20, so that heat from the inner box 20 to the outer box 10 is It is possible to more effectively block conduction so that the asphalt concrete contained in the inner box 20 can be maintained at an appropriate temperature.

The cover 30 may be formed on the upper side of the outer box 10 and the inner box 20 . The cover 30 is formed to cover upper sides of the outer box 10 and the inner box 20 to open and close the open upper sides of the outer box 10 and the inner box 20 .

The cover 30 may include an upper plate 31 and a lower plate 33 .

The cover 30 may be raised and lowered by a device such as a cylinder, a crane or a hoist to open and close the open upper side of the outer box 10 and the inner box 20 .

A plurality of fixing devices 50 for fixing the outer box 10 and the inner box 20 to each other are installed between the outer box 10 and the inner box 20, and the upper plate 31 of the cover 30 is provided. A plurality of fixing devices 50 ′ for fixing the upper plate 31 and the lower plate 33 of the cover 30 to each other may be installed between the lower plate and the lower plate 33 .

A plurality of fixing devices 50 installed between the outer box 10 and the inner box 20 pass through the outer box 10 from the outside of the outer box 10 , and then have one end in the inner box 20 . It is fastened to fix the outer box 10 to the outside of the inner box 20 .

Accordingly, the outer box 10 is supported and fixed from the outside of the inner box 20 by the plurality of fixing devices 50 .

A spaced space is formed between the outer box 10 and the inner box 20 by the plurality of fixing devices 50 .

In addition, a plurality of fixing devices 50 ′ installed between the upper plate 31 and the lower plate 33 of the cover 30 are provided while fixing the lower plate 33 of the cover 30 to the upper plate 31 . A spaced space may be formed between the upper plate 31 and the lower plate 33 of 30).

A plurality of fixing devices 50 ′ installed inside the cover 30 pass through the lower plate 33 from the outside of the lower plate 33 , and then one end is fastened to the upper plate 31 so that the lower plate 33 is the upper part. to be fixed to the plate (31).

That is, a plurality of fixing devices 50 for coupling and fixing the outer box 10 and the inner box 20 and a plurality of fixing devices 50 for coupling and fixing the upper plate 31 and the lower plate 33 of the cover 30 . '), a space is formed between the outer box 10 and the inner box 20 and between the upper plate 31 and the lower plate 33 of the cover 30.

Accordingly, a spaced space is formed between the outer box 10 and the inner box 20 and between the upper plate 31 and the lower plate 33 of the cover 30 to form a space between the inner box 20 and the asphalt concrete contained inside the inner box 20 . It is possible to prevent heat from being conducted to the upper plate 31 of the outer box 10 and the cover 30 , and between the outer box 10 and the inner box 20 and the upper plate 31 of the cover 30 . The inside of the space formed between the lower plate 33 and the lower plate 33 is filled with a high-temperature insulating material 60, which will be described later, to prevent the heat of the asphalt concrete contained in the asphalt concrete insulation box 1 from being conducted to the outside, thereby maintaining the temperature of the asphalt concrete more efficiently. there will be

In addition, the plurality of fixing devices (50, 50') by fixing the lower plate 33 and the outer box 10 of the cover 30 to a plurality of fixing bars (42, 42') having little thermal conductivity to be described later to the outer box (10) and the inner box 20 are blocked from being connected to each other by a plurality of fixing devices 50, the upper plate 31 and the lower plate 33 of the cover 30 are a plurality of fixing devices (50') The heat of asphalt concrete contained inside the inner box 20 is conducted to the upper plate 31 of the outer box 10 and the cover 30 by blocking the connection to each other by It becomes possible to prevent the temperature from falling.

A plurality of fixing brackets (40, 40') for fixing a plurality of fixing bars (42, 42') to be described later are coupled to the outer surface of the inner box 20 and the inner surface of the upper plate 31 of the cover 30. can That is, the plurality of fixing brackets (40, 40') is to block the above-described plurality of fixing devices (50, 50') from being directly connected to the inner box 20 and the upper plate 31 of the cover 30. It is formed on the outer surface of the inner box 20 and the inner surface of the upper plate 31 of the cover 30 to fix and couple the plurality of fixing bars 42 and 42' to be described later.

The plurality of fixing brackets 40 and 40' may be formed in a U-shape having a central portion concave inwardly. Accordingly, fixing bars 42 and 42' to be described later may be fitted into the concave central portion.

The plurality of fixing brackets 40 and 40' may be formed of steel, and one surface may be coupled to the outer surface of the inner box 20 or the inner side of the upper plate 31 of the cover 30 by coupling means such as welding.

A plurality of fixing bars 42 and 42' may be fitted to the plurality of fixing brackets 40 and 40', respectively. The plurality of fixing bars 42 and 42' are respectively fitted to the plurality of fixing brackets 40 and 40', and at the same time, one end of the plurality of fixing devices 50 and 50' is respectively fastened. That is, the plurality of fixing bars (42, 42') are respectively fixed to the plurality of fixing brackets (40, 40'), the plurality of fixing devices (50, 50') is the inner box 20 and the upper portion of the cover (30). By blocking direct contact with the plate 31, the heat of asphalt concrete contained in the asphalt concrete insulation box 1 is conducted to the outside through a plurality of fixing devices 50 and 50' to prevent the temperature of the asphalt concrete from lowering. do.

These fixing bars 42 and 42' may be made of wood or MC nylon having little thermal conductivity.

That is, by providing fixing bars 42 and 42' having little thermal conductivity between the plurality of fixing brackets 40 and 40' and the plurality of fixing devices 50 and 50', the plurality of fixing devices 50 and 50' ), it is possible to block the conduction of the heat of asphalt concrete contained inside the inner box 20 to the outer box 10 or to the upper plate 31 of the cover 30 .

Therefore, the heat of the asphalt concrete contained inside the inner box 20 by the plurality of fixing bars 42, 42' is conducted to the outside through the plurality of fixing devices 50, 50' to reduce the temperature of the asphalt concrete. that can be prevented.

For example, when the plurality of fixing devices 50, 50' are directly fastened to the inner box 20, the heat of asphalt concrete accommodated in the inner box 20 is transferred to the inner box 20 and the plurality of fixing devices 50, 50'. Through the conduction to the upper plate 31 of the outer box 10 and the cover 30, the temperature of the asphalt concrete contained in the asphalt concrete insulation box 1 may be a factor to decrease in a short time.

Therefore, in order to prevent this, the present invention provides a plurality of fixing bars having little thermal conductivity so that the plurality of fixing devices 50 and 50 ' do not directly contact the inner box 20 and the upper plate 31 of the cover 30 ( By fixing one end of each of the plurality of fixing devices (50, 50') to 42 and 42', not only the outer box 10 is stably fixed to the outside of the inner box 20, but also the outer box 10 It is possible to form a spaced space between the inner box 20 and the high temperature insulating material 60 to be described later.

The spaced space between the outer box 10 and the inner box 20 and the spaced space between the upper plate 31 and the lower plate 33 of the cover 30 may be filled with a high-temperature insulating material 60 . The high-temperature insulating material 60 is filled in the space between the outer box 10 and the inner box 20 and between the upper plate 31 and the lower plate 33 of the cover 30, and accommodated in the asphalt heat insulation box (1). It is possible to prevent the heat of asphalt concrete from being conducted to the outside.

These high-temperature insulation materials 60 are ceramic wool, mineral wool, cellulose, ceramic paper, urethane, ceramic wool, biocerak wool ) and rock wool can be selected and used.

An insulating board 80 may be further provided on each of the inner side surface of the outer box 10 and the upper side surface of the lower plate 33 of the cover 30 . The insulation board 80 may use a ceramic-based and silica-based insulation board such as a ceramic board, a ceramic cloth, a silica board, and a silica cloth.

Insulation board 80 is provided on the inner surface of the outer box 10 and the upper surface of the lower plate 33 of the cover 30, respectively, so that the heat of asphalt concrete accommodated in the asphalt heat insulation box 1 is transferred to the outer box 10 and the cover ( 30) not only can more effectively block conduction to the upper plate 31 of the outer box 10 and the outer air of the upper plate 31 of the cover 30, but also the outer box 10 and the inner box 20 It is possible to more effectively block conduction to the space between the space and the space between the upper plate 31 and the lower plate 33 of the cover 30 . That is, as the heat insulation effect is compounded by the high-temperature insulation material 60 and the insulation board 80 , it is possible to more effectively prevent the decrease in the temperature of the asphalt concrete contained in the inner box 20 .

An insulating resin 70 may be provided on the upper side of the space between the outer box 10 and the inner box 20 . The insulating resin 70 is provided so as to close the upper side of the separation space between the outer box 10 and the inner box 20 . The insulating resin 70 prevents direct contact between the outer box 10, the inner box 20, and the cover 30, so that the heat conduction is more effectively blocked, thereby preventing the temperature drop of the asphalt concrete.

In addition, the cover 30 may further include a heat insulating resin 70 on the lower side of the lower plate 33 , or the lower plate 33 of the cover 30 may be formed of a heat insulating resin 70 . Insulation provided on the upper side of the outer box 10 and the inner box 20 by providing the insulating resin 70 on the lower side of the cover 30 or forming the lower plate 33 of the cover 30 with the insulating resin 70 . The resin 70 and the insulating resin 70 provided on the lower side of the cover 30 come into contact with the lower plate 33 of the cover 30 formed of the insulating resin 70 or the outer box 10 and the inner box. Since the upper side of the 20 and the cover 30 are not in direct contact, it is possible to more effectively prevent the heat of the asphalt concrete from being conducted to the outside through the cover 30 .

Such a heat insulating resin 70 may use a bakelite plate or MC nylon plate having an excellent thermal insulation effect.

A packing material 71 is provided on each of the upper side of the insulating resin 70 provided on the upper side of the outer box 10 and the inner box 20 and the lower side of the insulating resin 70 provided on the lower side of the cover 30 . Also, the packing material 71 may be provided only at the lower edge of the insulating resin 70 provided on the lower side of the cover 30 or the lower edge of the lower plate 33 of the cover 30 formed of the insulating resin 70 . have.

Packing material 71 by packing the contact surface of the upper side of the cover 30 and the upper side of the outer box 10 and the inner box 20, the heat of the asphalt concrete loaded inside the asphalt insulation box 1 is released to the outside. can be effectively prevented.

As the packing material 71, foamed silicone can be used, and any material with low thermal conductivity and strong heat resistance can be used.

A desiccant is applied to the inner surface of the outer box 10 , the outer surface of the inner box 20 , the plurality of fixing brackets 40 and the plurality of fixing bars 42 , or the upper plate 31 and the lower plate 33 of the cover 30 . ) and a desiccant may be applied to the fixing bracket 40 ′ and the fixing bar 42 ′ provided on the inner surface of the upper plate 31 . The desiccant is a space between the outer box 10 and the inner box 20 and the space between the upper plate 31 and the lower plate 33 of the cover 30. to prevent occurrence.

The desiccant may be applied prior to filling the spaced space between the inner box 20 of the outer box 10 and the spaced space formed in the interior of the cover 30 with the high-temperature insulator 60 .

As such, by applying a desiccant to the inner surface of the outer box 10 and the outer surface of the inner box 20, the fixing bracket 40 and the fixing bar 42, the space between the outer box 10 and the inner box 20 It blocks the conduction of heat from the inner box 20 to the outer box 10 by moisture generated in the space, and the inner surface and upper plate 31 of the upper plate 31 and the lower plate 33 of the cover 30 . ) by applying a desiccant to the fixing bracket 40 ′ and the fixing bar 42 ′ provided on the inner surface of the cover 30 , by moisture generated in the space between the upper plate 31 and the lower plate 33 of the cover 30 . It blocks heat conduction from the lower plate 33 of the cover 30 to the upper plate 31 .

In addition, the outer box 10, the inner box 20, the upper plate 31 and the lower plate 33 of the cover 30, a plurality of fixing brackets 40, 40' and a plurality of fixing bars (42, 42') ) is prevented from being corroded by moisture to ensure the durability of the asphalt concrete insulation box (1).

The desiccant comprises the steps of adding 1 to 10 parts by weight of styrene-butadiene-styrene (SBS) to 100 parts by weight of insulating oil and heating and stirring to obtain a first mixture;

Adding 30 to 70 parts by weight of an asphalt compound with respect to 100 parts by weight of the first mixture and heating and stirring to obtain a second mixture;

Adding 1 to 5 parts by weight of polyaniline (PANI) with respect to 100 parts by weight of the second mixture and heating and stirring to obtain a third mixture;

Adding 6 to 12 parts by weight of zeolite with respect to 100 parts by weight of the third mixture and heating and stirring to obtain a fourth mixture;

To 100 parts by weight of the fourth mixture, 1 to 5 parts by weight of polybutene and 0.2 to 0.8 parts by weight of polymethyl methacrylate (PMMA) are added, stirred and cooled naturally to obtain a fifth mixture;

Adding 30 to 70 parts by weight of xylene with respect to 100 parts by weight of the fifth mixture, and adding and dissolving 10 to 40 parts by weight of Solvent No. 3 with respect to 100 parts by weight of the fifth mixture to obtain a sixth mixture can be manufactured through

An outlet 100 communicating with the outer box 10 and the inner box 20 may be formed on the lower side of one side of the outer box 10 and the lower side of the inner box 20 on one side. The outlet 100 is a passage for discharging the asphalt concrete loaded on the inside of the asphalt concrete insulation box 1 to the outside.

A heat insulating resin 70 may be provided around and outside the outlet 100 . Therefore, by preventing direct contact between the outer surface of the outlet 100 made of a material with high thermal conductivity and the opening and closing door 110 to be described later, the heat of the asphalt concrete is prevented from being emitted to the outside through the outlet 100 and the opening and closing door 110. can

The outlet 100 may be provided with an opening and closing door 110 formed in the same structure as the cover 30 . The opening and closing door 110 may be rotatably coupled to the upper side of the outlet 100 and to the outside of the outer box 10 by a hinge.

In addition, the opening/closing door 110 may automatically open and close the outlet 100 by the opening/closing cylinder 112 .

One side of the opening and closing cylinder 112 may be coupled to the opening and closing door 110 and the other side may be coupled to the external box 10 .

Accordingly, the opening/closing door 110 seals or opens the discharge port 100 by the operation of the opening/closing cylinder 112 so that the opening and closing of the discharge port 100 by the opening/closing door 110 may be made.

The opening/closing cylinder 112 may use a hydraulic cylinder or a pneumatic cylinder.

The opening and closing door 110 may be provided with a heat insulating resin 70 around the inner surface in contact with the outlet 100, or may be provided with a heat insulating resin 70 on the inner surface of the opening and closing door 110 in contact with the outlet 100. .

Therefore, since the discharge port 100 and the opening and closing door 110 are provided with the insulating resin 70, respectively, the discharge port 100 and the opening and closing door 110 are not in direct contact, so that heat conduction from the discharge port 100 to the opening and closing door 110 is prevented. can do.

The opening/closing door 110 may further include an auxiliary outlet and an auxiliary opening/closing door 120 . The auxiliary outlet and the auxiliary opening/closing door 120 are formed in a size smaller than the size of the opening/closing door 110 to be used when discharging an amount of asphalt concrete that is smaller than the amount of asphalt concrete discharged by the opening and closing door 110 .

The auxiliary outlet may be formed in the same shape as that of the outlet 100 , and the auxiliary opening/closing door 120 may be formed in the same shape as the opening/closing door 110 .

The auxiliary opening/closing door 120 is provided with an auxiliary opening/closing cylinder 122 to control the opening and closing of the auxiliary opening/closing door 120 . By forming an auxiliary outlet and an auxiliary opening and closing door 120 in the opening and closing door 110, when a small amount of asphalt concrete is discharged from the asphalt concrete insulation box 1, the outside air is less introduced into the asphalt concrete insulation box 1 by the opening and closing door 110 It is possible to prevent the temperature drop of the asphalt concrete.

The auxiliary opening/closing cylinder 122 may use a hydraulic cylinder or a pneumatic cylinder in the same manner as the above-described opening/closing cylinder 112 .

In addition, the auxiliary opening/closing door 120 may be provided with an opening/closing operation device capable of manually opening and closing in addition to opening and closing by the auxiliary opening/closing cylinder 122 .

The opening/closing operation device is formed in a locking structure that allows an operator to manually operate the opening and closing of the auxiliary opening and closing door, so that it is possible to easily operate the opening and closing of the auxiliary opening and closing door without driving the auxiliary opening/closing cylinder 122 .

In addition, the auxiliary outlet and the auxiliary opening and closing door 120 may be provided with an insulating resin 70 on the periphery of the auxiliary outlet and the inner surface of the auxiliary opening and closing door 120 in the same way as the discharge port 100 and the opening and closing door 110 .

That is, by providing the insulating resin 70 around the inner surface of the auxiliary opening and closing door 120 in contact with the auxiliary outlet to prevent direct contact between the auxiliary outlet and the auxiliary opening and closing door 120, the auxiliary outlet and the auxiliary opening and closing door 120 It is possible to prevent the temperature of the asphalt concrete from being conducted to the outside.

In addition, a packing material 71 is provided on one side of the insulating resin 70 provided around the perimeter of the outlet 100 and the inner surface of the opening and closing door 110 and the perimeter of the auxiliary outlet and the inner surface of the auxiliary opening and closing door 120 . The packing material 71 may be provided only on the edge of the insulating resin 70 provided around the inner surface of the opening and closing door 110 and the inner surface of the auxiliary opening and closing door 120 .

The packing material 71 packs the contact surface of the outlet 100 and the opening and closing door 110 and the auxiliary outlet and the auxiliary opening and closing door 120, so that the heat of the asphalt concrete loaded inside the asphalt concrete insulation box 1 is released to the outside. can be effectively prevented.

In case the asphalt concrete insulation box (1) is loaded on a general truck, not a dump truck, and asphalt concrete is transported to the construction site and discharged, an asphalt concrete insulation box (1) is placed under the outer box (10) of the asphalt concrete insulation box (1). A support plate 300 for supporting may be further provided.

At this time, one end of the support plate 300 is coupled to the lower end of the outer box 10 of the asphalt concrete insulation box 1 by a hinge, and the asphalt insulation box 1 rises or When descending, the asphalt concrete insulation box (1) is rotated based on the hinge coupling the outer box (10) and the support plate (300), so that the other side of the asphalt concrete insulation box (1) can be raised and lowered.

The elevating member 400 may be provided inside the separation space formed between the support plate 300 and the outer box 10 .

The lifting member 400 is formed of a hydraulic cylinder and a pneumatic cylinder, and is provided to mutually couple the support plate 300 and the outer box 10, and the lifting member 400 is driven by the tension and contraction of the hydraulic cylinder and the pneumatic cylinder. It is possible to raise and lower the other side of the asphalt concrete insulation box (1).

Accordingly, the asphalt concrete loaded in the asphalt concrete insulation box 1 can be easily discharged through the outlet 100 as the other side of the asphalt concrete insulation box 1 is raised or lowered through the driving of the lifting member 400 .

In addition, there is a method of discharging by the screw 200 formed inside the inner box 20 as another method of loading the asphalt concrete insulation box (1) on a general truck, not a dump truck, and transporting it to the construction site for discharge.

To this end, the screw 200 may be formed in the longitudinal direction toward the outlet 100 in the inner lower central portion of the inner box 20 .

The screw 200 may be rotatably formed in the longitudinal direction from one end of the inner side of the inner box 20 toward the outlet 100 .

This screw 200 may discharge asphalt loaded inside the inner box 20 by rotation to the outside through the outlet 100 .

That is, in the case of mounting the asphalt concrete insulation box 1 on a general truck other than a dump truck, even if the lifting member 400 is not provided in the lower part of the asphalt concrete insulation box 1, it is provided on the inside of the inner box 20. By moving the asphalt concrete loaded in the inner box 20 by the rotation of the screw 200 to the outlet 100, it is possible to easily discharge the asphalt concrete to the outside.

In addition, a weight sensor may be formed in the lower outer side of the outer box 10 . The weight sensor measures the overall weight of the asphalt concrete insulation box (1), so that the load amount of asphalt concrete can be grasped by the weight measurement value that is changed by the asphalt concrete load amount.

The weight sensor may be a generally used load cell, or a hydraulic sensor and a weight sensor may be used.

8 to 10 , the asphalt concrete insulation box according to an example of the present invention may be mounted on a loading part of a vehicle such as a truck. That is, in order to move the asphalt concrete insulation box 1 to the construction site, the asphalt concrete insulation box 1 can be mounted on a truck using a lifting device or a crane, and then fixed with a fixing device or the like.

Therefore, the asphalt concrete insulation box (1) is mounted on the truck and fixed, so that it is possible to transport asphalt concrete from the asphalt concrete manufacturing plant to the construction site.

When using the asphalt concrete insulation box (1) of the present invention mounted on a dump truck, the dump truck is equipped with an asphalt concrete insulation box (1) in which the support plate 300, the lifting member 400, and the screw 200 are not installed. It is possible to facilitate the discharge of asphalt concrete by the lifting device of the

In addition, when the asphalt concrete insulation box (1) of the present invention is mounted on a general truck rather than a dump truck, the asphalt insulation insulation box (1) in which the support plate 300 and the elevating member 400 are further installed in the asphalt insulation box (1) ), or by mounting the asphalt concrete insulation box (1) further installed with a screw 200 on the inside of the asphalt concrete insulation box (1), it is possible to facilitate the discharge of asphalt concrete.

The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

1: Ascon Insulation Box
10: outer box
20: inner box
30: cover 31: top plate
33: lower plate
40: fixing bracket 42: fixing bar
50: fixing device
60: high temperature insulation
70: insulating resin
71: packing material
80: insulation board
100: outlet
110: opening and closing door 112: opening and closing cylinder
120: auxiliary opening and closing door 122: auxiliary opening and closing cylinder
200: screw
300: support plate
400: elevating member

Claims (15)

In the asphalt concrete warming box that accommodates asphalt and maintains the appropriate temperature of the asphalt,
an outer box 10 with an open upper side;
an inner box 20 having a size smaller than that of the outer box 10 and having an open upper side provided inside the outer box 10;
a cover 30 formed to cover upper sides of the outer box 10 and the inner box 20;
It is installed between the outer box 10 and the inner box 20 to fix the outer box 10 to the outside of the inner box 20 and spaced between the outer box 10 and the inner box 20 a plurality of fixing devices 50 to form a space;
a plurality of fixing brackets 40 formed on the outer surface of the inner box 20;
a plurality of fixing bars (42) fitted to the plurality of fixing brackets (40) and to which one side of the plurality of fixing devices (50) is fastened;
A high-temperature insulating material (60) filled in the space between the outer box (10) and the inner box (20);
a desiccant applied to the inner surface of the outer box 10, the outer surface of the inner box 20, the plurality of fixing brackets 40 and the plurality of fixing bars 42;
Since the plurality of fixing devices 50 are respectively fixed to the plurality of fixing bars 42, one side of the plurality of fixing devices 50 is blocked from contacting with the outer surface of the inner box 20,
Ascon insulation box, characterized in that it prevents the generation of moisture due to the temperature difference between the outside air and asphalt concrete in the space formed between the outer box (10) and the inner box (20) by the desiccant.
The method according to claim 1,
The cover 30,
It includes an upper plate (31) and a lower plate (33),
A plurality of fixing devices 50' are installed between the upper plate 31 and the lower plate 33 to form a spaced apart space,
The spaced space is filled with a high-temperature insulating material (60),
A plurality of fixing brackets 40' are formed on the inner surface of the upper plate 31,
A plurality of fixing bars 42' to which one side of the plurality of fixing devices 50' are fastened are fitted to the plurality of fixing brackets 40',
The plurality of fixing devices 50 ′ are respectively fixed to the plurality of fixing bars 42 ′ so that one side of the plurality of fixing devices 50 ′ is in contact with the inner surface of the upper plate 31 of the cover 30 . is blocked,
Ascon thermal insulation box, characterized in that the desiccant is applied to the inner surface of the cover (30), the plurality of fixing brackets (40') and the plurality of fixing bars (42').
The method according to claim 1 or 2,
The fixing bar (42, 42') is asphalt concrete insulation box, characterized in that formed of wood or MC nylon.
The method according to claim 1,
Ascon thermal insulation box, characterized in that the upper side of the space between the outer box (10) and the inner box (20) is finished with an insulating resin (70).
3. The method according to claim 2,
Ascon insulation box, characterized in that the cover (30) is provided with an insulating resin (70) on the lower side of the lower plate (33) or the lower plate (33) is formed of an insulating resin (70).
6. The method of claim 5,
The lower edge of the insulating resin 70 provided on the lower side of the cover 30 or the lower edge of the lower plate 33 of the cover 30 formed of the insulating resin 70, characterized in that the packing material 71 is provided. Ascon Insulation Box.
3. The method according to claim 2,
Ascon thermal insulation box, characterized in that the inner surface of the outer box (10) and the upper surface of the lower plate (33) of the cover (30) are provided with an insulating board (80).
The method according to claim 1,
An outlet 100 communicating with the outer box 10 and the inner box 20 is formed on the lower side of one side of the outer box 10 and the lower side of the inner box 20 one side,
On the upper side of the outlet 100, the opening and closing door 110 for opening and closing the outlet 100 is rotatably formed by a hinge,
Ascon thermal insulation box, characterized in that the opening and closing door 110 is controlled by the opening and closing cylinder 112.
9. The method of claim 8,
Ascon thermal insulation box, characterized in that the heat insulating resin (70) is provided around the inner surface of the opening and closing door (110) in contact with the outlet (100).
10. The method according to any one of claims 4 to 6 and 9,
The insulating resin 70 is asphalt concrete insulation box, characterized in that formed of a bakelite plate or MC nylon plate.
10. The method of claim 9,
Ascon thermal insulation box, characterized in that the packing material (71) is provided at the edge of the insulating resin (70) provided around the inner surface of the opening and closing door (110).
9. The method of claim 8,
A screw 200 is rotatably formed in the inner lower central portion of the inner box 20 in the longitudinal direction toward the outlet 100,
Ascon thermal insulation box, characterized in that by the rotation of the screw (200), the asphalt concrete loaded inside the inner box (20) is moved in the direction of the outlet (100).
9. The method of claim 8,
In the opening and closing door 110,
Ascon thermal insulation box, characterized in that the auxiliary outlet and the auxiliary opening and closing door 120 of a size smaller than the size of the opening and closing door 110 are formed.
The method according to claim 1,
On the lower side of the outer box 10,
A support plate 300 for supporting the outer box 10 is provided,
Ascon insulation box, characterized in that the lifting member (400) is provided between the outer box (10) and the support plate (300).
The method according to claim 1 or 2,
The desiccant is
adding 1 to 10 parts by weight of styrene-butadiene-styrene (SBS) to 100 parts by weight of insulating oil and heating and stirring to obtain a first mixture;
adding 30 to 70 parts by weight of an asphalt compound based on 100 parts by weight of the first mixture and heating and stirring to obtain a second mixture;
adding 1-5 parts by weight of polyaniline (PANI) to 100 parts by weight of the second mixture and heating and stirring to obtain a third mixture;
adding 6 to 12 parts by weight of zeolite based on 100 parts by weight of the third mixture and heating and stirring to obtain a fourth mixture;
To obtain a fifth mixture by adding 1 to 5 parts by weight of polybutene and 0.2 to 0.8 parts by weight of polymethyl methacrylate (PMMA) with respect to 100 parts by weight of the fourth mixture, followed by stirring and natural cooling;
30 to 70 parts by weight of xylene is added with respect to 100 parts by weight of the fifth mixture, and 10 to 40 parts by weight of solvent No. 3 is added and dissolved with respect to 100 parts by weight of the fifth mixture to obtain a sixth mixture Step; Ascon insulation box, characterized in that manufactured through.

Images