CN212776284U - Vacuum insulator and heat insulating container - Google Patents

Abstract

The utility model provides a vacuum heat insulator, include: a metal plate; a glass plate disposed opposite to the metal plate at an interval; and a sealing structure which is arranged between the metal plate and the glass plate to seal and fix the metal plate and the glass plate, and a vacuum cavity is defined between the metal plate and the glass plate. The vacuum heat insulator of the utility model has impact resistance and stable structure, and can be used alone to manufacture a heat-insulating container. The utility model also provides a heat preservation container with this vacuum heat insulator.

Description

Vacuum insulator and heat insulating container

Technical Field

The utility model relates to a vacuum insulation technical field especially relates to a vacuum heat insulator and heat preservation container.

Background

Among the known vacuum thermal insulators, one is a vacuum insulation panel (i.e., VIP panel), which cannot be independently used due to limitations in strength and appearance, and needs to be embedded in a polyurethane foam layer for use, or additionally added with appearance protection at the periphery of the vacuum insulation panel, resulting in a complicated structure; the second type is vacuum glass, because the glass is transparent, the radiation heat transfer is large, and the glass is not impact-resistant, and meanwhile, the frame for fixing the glass is difficult to shape, and the manufacturing cost is high; the third is a vacuum steel plate heat insulator which is mainly used for barrel-shaped products, such as vacuum heat preservation cups, LNG tanks and the like, and the vacuum steel plate heat insulator is difficult to be made into a flat plate shape due to the heat bridge effect at the edge sealing position caused by the heat transfer of the inner shell and the outer shell, so that the application scene of the heat preservation container is limited.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to provide a stable and impact-resistant vacuum insulator.

It is a further object of the present invention to provide a vacuum thermal insulator having good thermal insulation.

Another further object of the present invention is to provide a heat-insulating container which is easy to assemble and has good heat-insulating effect.

In particular, the present invention provides a vacuum heat insulator comprising:

a metal plate;

a glass plate disposed opposite to the metal plate at a spacing; and

and the sealing structure is arranged between the metal plate and the glass plate to seal and fix the metal plate and the glass plate, and a vacuum cavity is defined between the metal plate and the glass plate.

Optionally, the sealing structure comprises a nickel plating layer and a solder sheet;

the upper surface of glass board forms the nickel coating, sets up the solder piece between the lower surface of nickel coating and metal sheet, realizes the sealed fixed of metal sheet and glass board through nickel coating, solder piece welding.

Optionally, the sealing structure comprises a metal sheet and a glass frit paste;

the upper surface of the glass plate is provided with glass powder slurry, a metal sheet is arranged between the glass powder slurry and the lower surface of the metal plate, and the metal plate and the glass plate are sealed and fixed through glass powder slurry melting and metal sheet welding.

Optionally, the sealing structure comprises a silica gel layer, and the metal plate and the glass plate are sealed and fixed through bonding of the silica gel layer.

Optionally, the vacuum thermal insulator further comprises: and a plurality of supports disposed within the vacuum chamber and configured to be secured to the metal plate and/or the glass plate to provide support between the metal plate and the glass plate.

Optionally, the metal plate has a thickness of 1-1.5 mm;

the thickness of the glass plate is 2-4 mm;

the distance between the metal plate and the glass plate is 0.15-1 mm;

the width of the sealing structure is 10-15 mm.

The utility model also provides a heat preservation container, include:

the storage box comprises a box body, a storage space is limited in the box body, and a storage opening for storing articles is formed in the box body; and

the door body is arranged on the front side of the storage opening and used for opening and closing the storage space; wherein

At least a part of the box body and/or the door body is the vacuum heat insulator.

Optionally, the metal plate has a body portion and a bent portion;

the body part is arranged opposite to the glass plate;

the bending part extends from the tail end of the body part to one side of the glass plate, so that a groove is defined between the inner surface of the bending part and the tail end of the glass plate.

Optionally, the case comprises: a main body frame, a fixing member, and a plurality of vacuum heat insulators;

the main body frame is a cuboid structure defined by a plurality of edges, a box body is defined by a plurality of vacuum heat insulators through fixing parts and the main body frame, wherein a metal plate of each vacuum heat insulator forms an outer shell of the box body, and a glass plate forms an inner shell of the box body.

Optionally, the fixing member has a main body portion, two extension portions and two insertion portions;

the two adjacent vacuum heat insulators are spliced and fixed through the fixing piece, the main body portion is arranged to be clamped between the outer surfaces of the bending portions of the two vacuum heat insulators, the two extending portions are arranged to extend between the edges of the glass plates and the main body frame of the two vacuum heat insulators from the main body portion respectively, and the two inserting portions are arranged to be inserted into the grooves of the two vacuum heat insulators respectively.

Optionally, the door body includes: a connecting frame, a door seal and a vacuum insulator;

the connecting frame is provided with a first frame part and a second frame part;

the first frame part is provided with a bulge matched with the groove, and the vacuum heat insulator and the connecting frame are fixed by matching the bulge with the groove;

the second frame part is formed on one side, close to the box body, of the first frame part, and the door seal and the connecting frame are fixed by fixing the door seal and the second frame part; and is

The metal plate of the vacuum insulator constitutes an outer panel of the door body, and the glass plate constitutes an inner panel of the door body.

The vacuum heat insulator of the utility model comprises the metal plate and the glass plate which are arranged at intervals, and the metal plate and the glass plate are sealed and fixed by the sealing structure, so that the vacuum heat insulator is impact-resistant and stable in structure, and can be used alone to manufacture a heat-insulating container; meanwhile, when the vacuum heat insulator is used for manufacturing a heat-insulating container, the metal plate is used as an outer plate of the heat-insulating container, and the glass plate is used as an inner plate of the heat-insulating container, so that the radiation heat transfer is small.

Further, the sealing structure of the vacuum heat insulator of the present invention comprises a nickel-plating layer and a solder sheet, or a metal sheet and a glass powder slurry, or a silica gel layer, so that the metal sheet and the glass sheet are tightly sealed, and the occurrence of gas leakage caused by loose sealing is avoided.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the present invention will be described in detail hereinafter, by way of illustration and not by way of limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic cross-sectional view of a vacuum heat insulator according to an embodiment of the present invention.

Fig. 2 is a schematic structural view of a sealing structure of the vacuum heat insulator shown in fig. 1.

Fig. 3 is another structural view of the sealing structure of the vacuum heat insulator shown in fig. 1.

Fig. 4 is still another structural view of the sealing structure of the vacuum thermal insulator shown in fig. 1.

Fig. 5 is a schematic structural view of an insulated container according to an embodiment of the present invention.

Fig. 6 is an exploded view of the thermal container shown in fig. 5.

Fig. 7 is a partial sectional structural view of a case of the thermal container shown in fig. 5.

Fig. 8 is a partially sectional structural schematic view of the door body of the insulated container shown in fig. 5.

Detailed Description

In the following description, for the vacuum heat insulator 100, the "up" and "down" orientations are orientations based on the vacuum heat insulator 100 itself as a reference, as shown in fig. 1; the orientations or positional relationships indicated for the thermal container 200 "front", "rear", "upper", "lower", "left", "right", and the like are orientations based on the thermal container 200 itself as a reference, as shown in fig. 5.

Fig. 1 is a schematic cross-sectional view of a vacuum heat insulator 100 according to an embodiment of the present invention. As shown in fig. 1, a vacuum heat insulator 100 according to an embodiment of the present invention includes: a metal plate 101, a glass plate 102, and a sealing structure 103. The glass plate 102 is disposed opposite to the metal plate 101 at a distance. A sealing structure 103 is provided between the metal plate 101 and the glass plate 102 to seal and fix the metal plate 101 and the glass plate 102, and a vacuum chamber 110 is defined between the metal plate 101 and the glass plate 102. The vacuum heat insulator 100 according to the embodiment of the present invention can reduce the convection heat transfer by evacuating between the hermetically sealed metal plate 101 and the glass plate 102, and the vacuum heat insulator 100 can be applied to the heat insulating container 200; the metal plate 101 is used as an outer plate of the vacuum heat insulator 100, so that the structure of the whole vacuum heat insulator 100 is stable and an independent appearance structure is maintained; the glass plate 102 is used as the inner plate of the vacuum heat insulator 100, so that the radiation heat transfer of the whole vacuum heat insulator 100 is small; and the vacuum heat insulator 100 may have a substantially flat plate-shaped structure, so that the application scenarios of the heat insulating container 200 are increased, and the user requirements are further satisfied. The vacuum chamber 110 of the vacuum heat insulator 100 according to the embodiment of the present invention has a vacuum degree of 10^-1-10^-3Pa. In some embodiments, the metal plate 101 is a stainless steel plate, which may be a stainless steel plate with a mirror or vapor-deposited inner surface. Such as 304 stainless steel. The use of the stainless steel plate ensures the strength of the vacuum insulator 100, provides an attractive appearance, reduces radiation heat transfer, and prevents gas leakage due to corrosion and corrosion.

The thickness of the metal plate 101 and the thickness of the glass plate 102 may be the same or different. In some embodiments, the thickness of the metal plate 101 is 1-1.5mm, such as 1mm, 1.2mm, 1.5 mm. The thickness of the glass plate 102 is 2 to 4mm, for example, 2mm, 3mm, 4 mm. Prior to the present invention, it was common for those skilled in the art to increase the thickness of the two-layer panel, for example, by using panels with a thickness greater than 10mm, in the face of the problem of ensuring the thermal insulation effect. While the applicant has creatively recognized that the thickness of the two-layer plate is not as large as possible, in the design of increasing the thickness of the plate, the problem of the overall weight of the vacuum heat insulator 100 is increased, which adversely affects the use of the vacuum heat insulator 100. Further, when the vacuum heat insulator 100 is applied to the heat insulating container 200, there is a problem that the internal volume of the heat insulating container 200 is reduced. For this reason, the applicant has made a departure from the conventional design idea and has creatively proposed to limit the thickness of the two-layer plate, thereby reducing the space occupied by the vacuum heat insulator 100 while securing the heat insulating effect. The width of the sealing structure 103 is 10-15mm, for example 10mm, 12mm, 15 mm. Through a lot of experimental studies, it is preferable to limit the width of the sealing structure 103 to 10mm-15mm, so that the sealing tightness can be ensured, and the volume reduction of the vacuum chamber 110 caused by the over-width of the sealing structure 103 can be avoided, and the thermal insulation effect of the vacuum thermal insulator 100 is good. The spacing between the metal plate 101 and the glass plate 102 is 0.15 to 1mm, for example, 0.15mm, 0.5mm, 1 mm. Setting the spacing between the metal plate 101 and the glass plate 102 to 0.15-1mm can meet different thermal insulation and product requirements. In addition, to further reduce the heat radiation of the glass, a LOW-E film layer may be added to the glass plate 102, and it should be understood that the addition of the LOW-E film layer may increase the manufacturing cost.

The sealing structure 103 needs to be able to tightly combine with the glass plate 102 and the metal plate 101 to ensure tight connection between the glass and the metal plate 101. Fig. 2 is a schematic structural view of the sealing structure 103 of the vacuum heat insulator 100 shown in fig. 1. Fig. 3 is another schematic structural view of the sealing structure 103 of the vacuum heat insulator 100 shown in fig. 1. Fig. 4 is still another structural view of the sealing structure 103 of the vacuum heat insulator 100 shown in fig. 1.

As shown in fig. 2, the sealing structure 103 includes a nickel plated layer 131 and a solder sheet 132; a nickel plating layer 131 is formed on the upper surface of the glass plate 102, a solder sheet 132 is disposed between the nickel plating layer 131 and the lower surface of the metal plate 101, and the metal plate 101 and the glass plate 102 are hermetically fixed by welding through the nickel plating layer 131 and the solder sheet 132. By forming the nickel plating layer 131 on the upper surface of the glass plate 102 and providing the solder sheet 132 between the nickel plating layer 131 and the lower surface of the metal plate 101, the metal plate 101 and the glass plate 102 can be tightly sealed, and air leakage caused by loose sealing can be avoided. The thickness of the nickel plating layer 131 may be 1 μm to 2 μm; the thickness of the solder sheet 132 may be 0.08mm to 0.12mm, for example 0.1 mm. The thickness of the nickel plating layer 131 is 1 μm-2 μm, which can meet the requirements of adhesion and metal welding. The thickness of the solder sheet 132 is 0.08mm-0.12mm, which not only gives consideration to the welding strength, but also avoids heat conduction.

The method for manufacturing the vacuum heat insulator 100 includes the steps of:

performing nickel plating treatment on the glass plate 102 to form a nickel plating layer 131 on the upper surface of the glass plate 102;

placing a solder sheet 132 between the nickel-plated layer 131 and the metal plate 101;

air between the glass plate 102 and the metal plate 101 is drawn out through a gap between the solder sheet 132 and the metal plate 101;

the solder pieces 132 are soldered and sealed to the metal plate 101, thereby obtaining the vacuum heat insulator 100.

The nickel plating treatment of the glass plate 102 may be performed by a method of plating nickel on glass as disclosed in the prior art, and will not be described in detail herein. The solder flakes 132 may be silver copper solder flakes, Ag: 72 parts of Cu: 28. the vacuum-pumping treatment and the solder-sealing treatment are performed in a vacuum furnace. The vacuum treatment is vacuum treatment until the vacuum degree is 10^-1-10^-3Pa. The soldering temperature is 750 ℃ to 850 ℃, for example 800 ℃. After the treatment is completed, the temperature is maintained for 1min to 2min, and then the vacuum heat insulator 100 is taken out of the vacuum furnace.

As shown in fig. 3, in other embodiments, the sealing structure 103 includes a metal sheet 141 and a glass frit paste 142; the glass frit paste 142 is disposed on the upper surface of the glass plate 102, the metal plate 141 is disposed between the glass frit paste 142 and the lower surface of the metal plate 101, and the metal plate 101 and the glass plate 102 are sealed and fixed by melting the glass frit paste 142 and welding the metal plate 141. The metal sheet 141 is fixed on the surface of the glass plate 102 by the glass powder slurry 142, and the glass plate 102 and the metal plate 101 are sealed and fixed by the metal sheet 141, so that the metal plate 101 and the glass plate 102 can be tightly sealed, and air leakage caused by loose sealing can be avoided. The metal sheet 141 may use a metal tape. The metal sheet 141 may be a kovar sheet, such as ferrochrome, iron-nickel-cobalt, or the like.

The method for manufacturing the vacuum heat insulator 100 includes the steps of:

coating a glass frit paste 142 on the metal sheet 141;

bonding the metal sheet 141 to the upper surface of the glass plate 102, and heating and melting the metal sheet 141 to fix the metal sheet 141 to the glass plate 102;

air between the glass plate 102 and the metal plate 101 is drawn out through a gap between the metal sheet 141 and the metal plate 101;

the metal piece 141 and the metal plate 101 are welded and sealed to obtain the vacuum heat insulator 100.

The temperature for heating and melting is 440-460 ℃, and the slurry can be melted, but the glass can not be melted. The vacuum-pumping treatment and the solder-sealing treatment are performed in a vacuum furnace. The vacuum treatment is vacuum treatment until the vacuum degree is 10^-1-10^-3Pa. The soldering temperature is 750 ℃ to 850 ℃, for example 800 ℃. After the treatment is completed, the temperature is maintained for 1min to 2min, and then the vacuum heat insulator 100 is taken out of the vacuum furnace.

In still other embodiments, as shown in fig. 4, the sealing structure 103 includes a silicone gel layer 150; the metal plate 101 and the glass plate 102 are sealed and fixed through the adhesion of the silica gel layer 150, and air leakage caused by loose sealing is avoided. The silica gel can be quick-drying silica gel, has the strength performance of structural adhesive and the toughness of the silica gel, has good air tightness, and can be tightly combined with the glass plate 102 and the metal plate 101. In some embodiments, the silicone gel layer 150 has a thickness of 0.3mm to 1mm, e.g., 0.3mm, 0.5mm, 1 mm. The thickness of the silica gel layer 150 is 0.3mm-1mm, which can give consideration to structural strength, toughness, heat insulation and air release.

As shown in fig. 1, in some embodiments, the vacuum thermal insulator 100 further includes: a plurality of supports 104, disposed within the vacuum chamber 110, are configured to be secured to the metal plate 101 and/or the glass plate 102 to provide support between the metal plate 101 and the glass plate 102. By providing a plurality of supporting members 104 in the vacuum chamber 110, it is possible to provide support to the metal plate 101 and the glass plate 102, enhancing the strength of the entire vacuum heat insulator 100; the support member 104 is directly fixed to the metal plate 101 and/or the glass plate 102, so that the process of disposing the support member 104 is simplified and the manufacturing process of the entire vacuum heat insulator 100 is simplified. The support 104 may be, for example, a quartz glass column, a teflon column, a dotted ceramic or glass bead, which may be bonded to the lower surface of the metal plate 101 and/or the upper surface of the glass plate 102 with silica gel.

The vacuum heat insulator 100 according to the embodiment of the present invention solves the problems of structural strength, heat transfer, support, and sealing, so that the vacuum heat insulator 100 can be practically produced and applied, and particularly, the vacuum heat insulator 100 can be applied to the heat insulating container 200. Fig. 5 is a schematic structural diagram of an insulated container 200 according to an embodiment of the present invention. The thermal container 200 includes a case 300 and a door 400. The case 300 defines a storage space 210 therein, and the case 300 is provided with a storage opening for storing articles. The door 400 is provided in front of the storage opening to open and close the storage space 210. At least a part of the cabinet 300 and/or the door 400 is the vacuum insulator 100. Preferably, the entire cabinet 300 and the door 400 are vacuum heat insulators 100. As shown in fig. 5, the storage opening of the cabinet 300 is usually located on the front side of the cabinet 300, and the door 400 is correspondingly provided on the front side of the cabinet 300. The vacuum heat insulator 100 according to the embodiment of the present invention may have a substantially flat plate shape, so that the heat insulating container 200 manufactured by the vacuum heat insulator may have various modifications, thereby increasing the application scenarios of the heat insulating container 200. The thermal container 200 of the present invention can be designed and used as a part of an intelligent home.

Referring to fig. 5, in some embodiments, the box 300 includes a main frame 301, a fixing member 302, and a plurality of vacuum heat insulators 100, wherein the main frame 301 is a rectangular parallelepiped structure defined by a plurality of ribs, the plurality of vacuum heat insulators 100 are fixed to the main frame 301 via the fixing member 302 to define the storage space 210, the metal plate 101 forms an outer shell of the box 300, the glass plate 102 forms an inner shell of the box 300, and an inner side of the glass plate 102 facing away from the metal plate 101 is the storage space 210. The vacuum heat insulator 100 forms the case 300, so that the wall thickness of the heat insulating container 200 is kept small, the heat insulating effect of the heat insulating container 200 can be ensured, and the internal volume of the heat insulating container 200 is increased. Fig. 6 is an exploded view of the thermal container 200 shown in fig. 5. The heat insulating container 200 of the embodiment of the present invention forms the box 300 by fixing the vacuum heat insulator 100 and the main body frame 301 by the fixing member 302, so that the heat insulating container 200 has a simple manufacturing process and a reduced cost.

Referring to fig. 1 and 2, a metal plate 101 of a vacuum heat insulator 100 according to an embodiment of the present invention has a body portion 111 and a bent portion 112; the body portion 111 is disposed opposite to the glass plate 102; the bent portion 112 extends from the end of the body portion 111 toward the side of the glass sheet 102 such that a groove 113 is defined between the inner surface of the bent portion 112 and the end of the glass sheet 102.

Fig. 7 is a partial sectional structural view of the box 300 of the thermal container 200 shown in fig. 5. The fixing member 302 of the case 300 of the thermal container 200 according to the embodiment of the present invention includes a main body 321, two extending portions 322, and two insertion portions 323. The two adjacent vacuum heat insulators 100 are connected and fixed by the fixing member 302, wherein the main body 321 is disposed to be sandwiched between the outer surfaces of the bending portions 112 of the two vacuum heat insulators 100, the two extending portions 322 are disposed to extend from the main body 321 to between the edges of the glass plates 102 of the two vacuum heat insulators 100 and the main body frame 301, and the two inserting portions 323 are disposed to be inserted into the grooves 113 of the two vacuum heat insulators 100. By configuring the fixing member 302 to have the main body 321, the two extending portions 322, and the two inserting portions 323, the vacuum heat insulator 100 is configured to have the groove 113 structure, so that the splicing between the vacuum heat insulators 100 and the fixing between the vacuum heat insulator 100 and the main body frame 301 are very convenient to be realized, and the extending portions 322 and the inserting portions 323 are configured to be stably fixed. The fastener 302 may be a plastic piece, such as ABS plastic. In addition, an adhesive 600 may be used between the glass plate 102 and the extension 322 of the fixture 302 to make the assembly more stable.

With continued reference to fig. 5, in some embodiments, the door 400 of the thermal container 200 according to embodiments of the present invention includes: connecting the frame 401, the dock seal 402, and the vacuum insulator 100. The connection frame 401 has a first frame portion 411 and a second frame portion 412; the first frame portion 411 has a protrusion (not numbered) matching the groove 113, and the fixing of the vacuum insulator 100 to the connection frame 401 is achieved by matching the protrusion with the groove 113. The second frame portion 412 is formed on the side of the first frame portion 411 close to the box body 300, and the door seal 402 and the connecting frame 401 are fixed by fixing the door seal 402 and the second frame portion 412, wherein the metal plate 101 constitutes an outer plate of the door body 400 and the glass plate 102 constitutes an inner plate of the door body 400. Fig. 8 is a partially sectional structural schematic view of the door 400 of the insulated container 200 shown in fig. 5. The side surface of the second frame portion 412 away from the first frame portion 411 is recessed inward to form a receiving cavity 413. The dock seal 402 includes an air bag 421, a base 422, and a magnetic strip 423; the base 422 is accommodated in the accommodating chamber 413; the magnetic strip 423 is provided on the airbag 421, and engages with the metal plate 101 of the case 300 to attach the door seal 402 to the case 300. The door body 400 has a smart structure, the first frame portion 411 and the second frame portion 412 of the connecting frame 401 are used for firmly fixing the vacuum heat insulator 100, the door seal 402 and the connecting frame 401, and meanwhile, the appearance of the door body 400 can be kept integral, and the sensory experience of a user is improved. The connecting frame 401 may be a plastic piece, such as ABS plastic. In addition, an adhesive 600 may be used between the glass plate 102 and the connection frame 401 to make the assembly more stable. As shown in fig. 5, a plurality of bottle holders 500 may be provided inside the door 400 to store articles.

The vacuum heat insulator 100 of the embodiment of the present invention comprises the metal plate 101 and the glass plate 102 which are oppositely arranged at an interval, and the sealing structure 103 is used to seal and fix the metal plate 101 and the glass plate 102, so that the vacuum heat insulator 100 is impact-resistant and stable in structure, and can be used alone to manufacture the heat-insulating container 200; meanwhile, when the vacuum heat insulator 100 is used to manufacture the heat insulating container 200, the metal plate 101 is used as an outer plate of the heat insulating container 200, and the glass plate 102 is used as an inner plate of the heat insulating container 200, so that radiation heat transfer is small.

Further, the sealing structure 103 of the vacuum thermal insulator 100 according to the embodiment of the present invention includes the nickel plating layer 131 and the solder sheet 132, or the metal sheet 141 and the glass frit slurry 142, or the silica gel layer 150, so that the metal plate 101 and the glass plate 102 can be tightly sealed, and the occurrence of air leakage caused by loose sealing can be avoided.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been shown and described in detail herein, many other variations and modifications can be made, consistent with the principles of the invention, which are directly determined or derived from the disclosure herein, without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and interpreted to cover all such other variations or modifications.

Claims (11)

1. A vacuum thermal insulator, comprising:

a metal plate;

a glass plate disposed opposite to the metal plate at an interval; and

and the sealing structure is arranged between the metal plate and the glass plate to seal and fix the metal plate and the glass plate, and a vacuum cavity is defined between the metal plate and the glass plate.

2. The vacuum thermal insulator according to claim 1,

the sealing structure comprises a nickel plating layer and a solder sheet;

the upper surface of the glass plate is provided with the nickel plating layer, the solder sheet is arranged between the nickel plating layer and the lower surface of the metal plate, and the metal plate and the glass plate are sealed and fixed by welding the nickel plating layer and the solder sheet.

3. The vacuum thermal insulator according to claim 1,

the sealing structure comprises a metal sheet and glass powder slurry;

the glass powder slurry is arranged on the upper surface of the glass plate, the metal sheet is arranged between the glass powder slurry and the lower surface of the metal plate, and the metal plate and the glass plate are sealed and fixed through melting of the glass powder slurry and welding of the metal sheet.

4. The vacuum thermal insulator according to claim 1,

the sealing structure comprises a silica gel layer, and the metal plate and the glass plate are sealed and fixed through bonding of the silica gel layer.

5. The vacuum thermal insulator of claim 1, further comprising:

a plurality of supports disposed within the vacuum chamber configured to be secured to the metal plate and/or the glass plate to provide support between the metal plate and the glass plate.

6. The vacuum thermal insulator according to claim 1,

the thickness of the metal plate is 1-1.5 mm;

the thickness of the glass plate is 2-4 mm;

the distance between the metal plate and the glass plate is 0.15-1 mm;

the width of the sealing structure is 10-15 mm.

7. An insulated container, comprising:

the storage box comprises a box body, a storage space is limited in the box body, and a storage opening for storing articles is formed in the box body; and

the door body is arranged on the front side of the storage opening and used for opening and closing the storage space; wherein

At least a part of the box body and/or the door body is the vacuum heat insulator according to any one of claims 1 to 6.

8. The thermal container according to claim 7,

the metal plate is provided with a main body part and a bending part;

the body part is arranged opposite to the glass plate;

the bent part extends from the tail end of the body part towards one side of the glass plate, so that a groove is defined between the inner surface of the bent part and the tail end of the glass plate.

9. The thermal container according to claim 8,

the box body comprises: a main body frame, a fixing member and a plurality of vacuum heat insulators;

the main body frame is a rectangular parallelepiped structure defined by a plurality of ribs, and the vacuum heat insulators are fixed to the main body frame via the fixing members to define the box body, wherein the metal plate of the vacuum heat insulator forms an outer shell of the box body, and the glass plate forms an inner shell of the box body.

10. The thermal container according to claim 9,

the fixing piece is provided with a main body part, two extending parts and two inserting parts;

the two adjacent vacuum heat insulators are spliced and fixed through the fixing piece, the main body portion is configured to be clamped between outer surfaces of the bending portions of the two vacuum heat insulators, the two extending portions are configured to extend between the glass plates of the two vacuum heat insulators and the edges of the main body frame from the main body portion respectively, and the two insertion portions are configured to be inserted into the grooves of the two vacuum heat insulators respectively.

11. The thermal container according to claim 8,

the door body includes: connecting a frame, a door seal and the vacuum insulator;

the connecting frame is provided with a first frame part and a second frame part;

the first frame part is provided with a protrusion matched with the groove, and the vacuum heat insulator is fixed with the connecting frame by matching the protrusion with the groove;

the second frame portion is formed on one side, close to the box body, of the first frame portion, and the door seal and the connecting frame are fixed by fixing the door seal and the second frame portion; and is

The metal plate of the vacuum insulator constitutes an outer plate of the door body, and the glass plate constitutes an inner plate of the door body.

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