Refrigeration container
By designing a refrigeration container and utilizing a combination of semiconductor cooling chips and heat dissipation components, the problem of insufficient cooling of alcoholic beverages at room temperature was solved, achieving continuous temperature control.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 深圳市岩竹实业有限公司
- Filing Date
- 2025-05-20
- Publication Date
- 2026-07-14
AI Technical Summary
In existing technologies, methods for cooling alcoholic beverages such as beer at room temperature cannot meet users' temperature requirements.
A refrigeration container was designed, comprising a container body and a refrigeration component. It utilizes a semiconductor refrigeration chip for cooling and heat dissipation, conducts heat through a thermally conductive material, and is equipped with a heat dissipation component to dissipate heat to the outside, thereby maintaining a stable liquid temperature inside the container.
It achieves continuous cooling of the liquid inside the container at room temperature, maintaining the temperature within a preset range to meet the user's drinking experience needs.
Smart Images

Figure CN224498915U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of containers, and more particularly to refrigeration containers. Background Technology
[0002] Alcoholic beverages, such as beer, require cooling in certain situations. There are two main methods for cooling alcoholic beverages like beer: the first is to place them in a refrigerator for cooling; the second is to add ice cubes for cooling.
[0003] In practical applications, alcoholic beverages such as beer are often kept at room temperature, and the two cooling methods mentioned above often cannot meet users' temperature requirements for alcoholic beverages such as beer. Utility Model Content
[0004] In view of this, this application provides a refrigeration container to solve one of the above problems.
[0005] To achieve one or more of the above objectives or other objectives, this application proposes:
[0006] A refrigeration container includes: a container body having a cavity for containing liquid, at least a portion of the container body being thermally conductive; a refrigeration assembly having a refrigeration portion and a heating portion disposed opposite to each other, the refrigeration portion contacting the container body for cooling the container body, thereby cooling the liquid contained therein; and a heat dissipation assembly contacting the heating portion to dissipate heat from the refrigeration assembly to the outside.
[0007] Implementing the embodiments of this application will have the following beneficial effects:
[0008] After adopting the above-mentioned refrigeration container, the refrigeration components can be used to cool down the liquid in the container cavity to meet the user's drinking experience. Attached Figure Description
[0009] This application will describe the embodiments in conjunction with the accompanying drawings. The drawings are for illustrative purposes only and are used to describe the embodiments. Without departing from the principles of this application, those skilled in the art can easily make other embodiments based on the steps described below.
[0010] Figure 1 This is a perspective view of a refrigeration container provided in an embodiment of this application.
[0011] Figure 2 This is an exploded view of a refrigeration container provided in an embodiment of this application.
[0012] Figure 3This is a cross-sectional view of a refrigeration container provided in an embodiment of this application.
[0013] Figure 4 A perspective view of a refrigeration container provided in another embodiment of this application.
[0014] Figure 5 An exploded view of a refrigeration container provided for another embodiment of this application.
[0015] Figure 6 A cross-sectional view of a refrigeration container provided in another embodiment of this application.
[0016] Figure 7 A perspective view of a refrigeration container provided in yet another embodiment of this application.
[0017] Figure 8 An exploded view of a refrigeration container provided in yet another embodiment of this application.
[0018] Figure 9 A cross-sectional view of a third type of refrigeration container provided in yet another embodiment of this application.
[0019] Figure 10 A perspective view of a fourth type of refrigeration container provided in yet another embodiment of this application.
[0020] Figure 11 A cross-sectional view of a refrigeration container provided in another embodiment of this application mainly shows the evaporator, condenser, compressor and throttle valve therein.
[0021] Figure 12 The cross-sectional view of the refrigeration container provided in another embodiment of this application mainly shows another distribution structure of the evaporator, condenser, compressor and throttling device therein.
[0022] Figure 13 for Figure 12 The diagram shows the three-dimensional structure of the condenser.
[0023] Figure 14 A cross-sectional view of a refrigeration container provided in another embodiment of this application mainly shows that the evaporator inside is designed in a spiral shape.
[0024] Figure 15 This is a cross-sectional view of a refrigeration container provided in an embodiment of this application, mainly showing the relationship between the condenser and the heat-conducting components inside.
[0025] Figure 16 This is an exploded view of a refrigeration container provided in an embodiment of this application.
[0026] Figure 17 This is a cross-sectional view of a refrigeration container provided in an embodiment of this application.
[0027] Figure 18A cross-sectional view of a refrigeration container provided in another embodiment of this application.
[0028] Figure 19 A perspective view of a refrigeration container provided in yet another embodiment of this application.
[0029] Figure 20 An exploded view of a refrigeration container provided in yet another embodiment of this application.
[0030] Figure 21 A cross-sectional view of a refrigeration container provided in yet another embodiment of this application. Detailed Implementation
[0031] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of them. The following description of at least one exemplary embodiment is merely illustrative and is in no way intended to limit the application or its application or use. All other embodiments obtained by those skilled in the art based on the embodiments of this application without creative effort are within the protection scope of this application.
[0032] In this document, references to "embodiment" or "implementation" mean that a particular feature, structure, or characteristic described in connection with an embodiment or implementation may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.
[0033] like Figures 1 to 3 As shown, this utility model embodiment provides a refrigeration container 100, which can hold liquids such as alcoholic beverages. For example, the refrigeration container 100 can hold beer. This application embodiment uses the refrigeration container 100 holding beer as an example for illustration. It should be understood that the refrigeration container 100 in this application embodiment is not limited to holding beer, but can also hold other alcoholic beverages that can be cooled.
[0034] After beer is placed in the refrigeration container 100, the refrigeration container 100 can cool the beer inside. In some cases, the refrigeration container 100 can continuously cool the beer inside. Even if the refrigeration container 100 is placed at room temperature, such as 30 degrees Celsius, the refrigeration container 100 can maintain the beer temperature at a preset temperature, such as 10 degrees Celsius, for a long time.
[0035] The refrigeration container 100 has a height direction D1. It should be noted that the height direction D1 of the refrigeration container 100 can also be understood as the vertical direction D1 of the refrigeration container 100.
[0036] Please continue reading. Figures 1 to 3 The refrigerated container 100 includes a container body 101 capable of holding liquids such as beer. The container body 101 has an opening 124 located at the top of the container body 101, through which liquids such as beer can be poured into the container body 101.
[0037] For example, the container body 101 includes a first container body 101 having a first receiving cavity 115 and a second container body 120 having a second receiving cavity 123. The first container body 101 and the second container body 120 are sealed together so that the first receiving cavity 115 and the second receiving cavity 123 communicate. Alternatively, the first container body 101 and the second container body 120 are joined and sealed to form the container body 101. The first container body 101 and the second container body 120 are capable of jointly containing liquids such as beer.
[0038] It should be understood that the sealed connection between the first container body 101 and the second container body 120 can prevent leakage at the connection point between the first container body 101 and the second container body 120.
[0039] For example, the first container body 101 and the second container body 120 are arranged along the height direction D1 of the refrigeration container 100, or in other words, the first container body 101 and the second container body 120 are joined and sealed along the vertical direction D1 of the refrigeration container 100 to form the container body 101. For example, the second container body 120 is connected to the top of the first container body 101. The opening 124 of the container body 101 is located at the top of the second container body 120. It should be noted that the joining direction of the first container body 101 and the second container body 120 is not limited to the vertical direction D1 of the refrigeration container 100; for example, it can be joined and sealed along the circumferential direction of the refrigeration container 100 to form the container body 101.
[0040] For example, the sealing connection between the first container body 101 and the second container body 120 includes a sealing ring 170 connecting the first container body 101 and the second container body 120. It should be understood that the sealing connection between the first container body 101 and the second container body 120 is not limited to the sealing ring 170. One of the first container body 101 and the second container body 120 may have a sealing groove 116, the sealing ring 170 may be installed within the sealing groove 116, and the other of the first container body 101 and the second container body 120 may press against the sealing ring 170. This achieves a sealing connection between the first container body 101 and the second container body 120.
[0041] For example, the sealing groove 116 is formed in the first container body 101. It should be understood that the sealing groove 116 may also be formed in the second container body 120.
[0042] For example, the sealing ring 170 has certain deformation characteristics. When the sealing ring 170 is subjected to external forces such as the compression of the second container body 120, the sealing ring 170 will undergo a small amount of deformation, which can further improve the sealing effect of the connection between the first container body 101 and the second container body 120.
[0043] It should be noted that containers used to hold liquids such as beer are often thinner, and creating grooves in thinner containers can easily lead to damage or instability during the connection process.
[0044] It should also be noted that glass is often used to hold liquids such as beer. Creating grooves in the glass, especially in thinner glass, can easily lead to damage to the container and instability during the connection process.
[0045] In this embodiment of the application, to increase the strength of both the first container body 101 and the second container body 120, as well as the connection stability between them, the first container body 101 is made of a metal material, such as stainless steel. Furthermore, at least a portion of the thickness of the first container body 101 is greater than the thickness of the second container body 120. For example, the thickness of the first container body 101 at the location where the sealing groove 116 is formed is at least greater than the thickness of the second container body 120. In actual manufacturing, forming the sealing groove 116 on the first container body 101, which is made of metal and is thicker than the second container body 120, not only maintains the strength of both the first container body 101 and the second container body 120, but also maintains the connection stability and sealing performance between them.
[0046] Specifically, the sealing groove 116 is formed at one end of the first container body 101 near the second container body 120, and the end of the second container body 120 near the first container body 101 presses against the sealing ring 116.
[0047] For example, the first container body 101 includes a first sidewall 112 and a first connecting portion 111 connected together, wherein the first connecting portion 111 is connected to the top of the first sidewall 112, such that the first sidewall 112 and the first connecting portion 111 are integrally formed. The second container body 120 includes a second sidewall 122 and a second connecting portion 121 connected together, wherein the first connecting portion 111 and the second connecting portion 121 are connected, and the first connecting portion 111 covers the second connecting portion 121, thereby further increasing the connection stability and sealing performance between the first container body 101 and the second container body 120.
[0048] For example, the thickness of the first sidewall 112 is greater than the thickness of the second sidewall 122. A sealing groove 116 is formed at one end of the first sidewall 112 near the first connecting portion 111, and the first connecting portion 111 is located outside the sealing groove 116. The second connecting portion 121 presses against the sealing ring 170 placed in the sealing groove 116.
[0049] For example, the end of the first connecting portion 111 away from the first sidewall 112 abuts against the second sidewall 122, and the outer surface of the first connecting portion 111 and the outer surface of the second sidewall 122 smoothly transition. For example, the outer surface of the first connecting portion 111 and the outer surface of the second sidewall 122 are flush. Or, the outer surfaces at the junction of the first container body 101 and the second container body 120 are coplanar and smoothly transition.
[0050] For example, the first connecting portion 111 and the second connecting portion 121 are threaded together. For instance, the inner surface of the first connecting portion 111 is provided with a first thread 117, and the outer surface of the second connecting portion 121 is provided with a second thread 125, and the first thread 117 and the second thread 125 are connected together.
[0051] For example, the thickness of the first connecting portion 111 is less than the thickness of the first sidewall 112 and the thickness of the second sidewall 122. The thickness of the second connecting portion 121 is less than the thickness of the first sidewall 112.
[0052] The second container body 120 is transparent. For example, the second container body 120 is made of glass or plastic.
[0053] For example, the first container body 101 is thermally conductive, or in other words, the first container body 101 has thermal conductivity. For instance, the first container body 101 may be made of a metal material.
[0054] Please continue reading. Figures 1 to 3 The refrigeration container 100 also includes a refrigeration component 130 and a heat dissipation component 140. In this embodiment, the refrigeration component 130 is a thermoelectric cooler, the refrigeration portion 131 is the refrigeration portion of the thermoelectric cooler, and the heating portion 132 is the heating surface of the thermoelectric cooler. The refrigeration portion 131 is in contact with the first container body 101, and the heat dissipation component 140 is in contact with the heating portion 132. The refrigeration component 130 can conduct the heat of the liquid, such as beer, contained in the first receiving cavity 115 to the heat dissipation component 140 through the first container body 101, and the heat dissipation component 140 can dissipate the heat from the refrigeration component 130 to the outside. For example, when the refrigeration component 130 is energized, it conducts the heat of the liquid, such as beer, contained in the first receiving cavity 115 to the heat dissipation component 140 through the first container body 101, and the heat dissipation component 140 dissipates the heat from the refrigeration component 130 to the outside.
[0055] For example, the cooling component 130 and the heat dissipation component 140 can be energized simultaneously. It should be noted that in some cases, the cooling component 130 and the heat dissipation component 140 may not be energized simultaneously, such as the heat dissipation component being energized first and the heat dissipation component 140 being energized later, and the interval between their energization is less than a preset value, such as 1 second, 2 seconds, 3 seconds, or other values.
[0056] For example, the heat dissipation assembly 140 may include one or more heat sinks. For example, the heat dissipation assembly 140 includes a first heat sink 141 and a plurality of second heat sinks 142, the plurality of second heat sinks 142 being spaced apart and connected to one side of the first heat sink 141, and the other side of the first heat sink 141 being in contact with the heating portion 132. That is, the first heat sink 141 is disposed between the cooling assembly 130 and the plurality of second heat sinks 142.
[0057] For example, the heat dissipation assembly 140 also includes one or more fans 143. This embodiment of the application describes the heat dissipation assembly 140 as including a first heat sink 141, a plurality of second heat sinks 142, and a fan 143. The fan 143 is disposed below the plurality of second heat sinks 142, that is, the plurality of second heat sinks 142 are located between the fan 143 and the first heat sink 141, and the fan 143 can accelerate heat dissipation.
[0058] The refrigeration container 100 also includes a power connector 180, which is connected to the heat dissipation assembly 140 and the refrigeration assembly 130, for example, via a wire. The power connector 180 can be connected to AC power via a charging cable to supply power to the refrigeration assembly 130 and the heat dissipation assembly 140, enabling the refrigeration assembly 130 and the heat dissipation assembly 140 to operate when powered on.
[0059] In other alternative embodiments, the refrigeration container 100 further includes a power source such as a battery, which is connected to the heat dissipation assembly 140 and the refrigeration assembly 130 via wires. The battery can directly power the power connector 180 and the heat dissipation assembly 140. The battery may be a rechargeable battery, such as one connected to the power connector 180. In other alternative embodiments, the battery may be a disposable battery.
[0060] In this embodiment, the cooling component 130, the heat dissipation component 140, and the power connector 180 can all be installed in the mounting shell 150. For example, the mounting shell can be a single shell structure or a shell assembly composed of multiple shell structures. It should be understood that the mounting shell 150 not only serves as a carrier for the cooling component 130, the heat dissipation component 140, and the power connector 180, but is also connected to the container body 101. The mounting shell 150 can be located at the top or bottom of the container body 101. When the mounting shell 150 is located at the bottom of the container body 101, it can support the container body 101. For example, the mounting shell 150 is connected to the first container body 101, and the second container body 120, the first container body 101, and the mounting shell 150 are arranged sequentially in the height direction D1 of the cooling container 100.
[0061] For example, the first container body 101 further includes an end wall 114 and a third connecting portion 113, the third connecting portion 113 being connected to the periphery of the end wall 114, and the end of the third connecting portion 113 away from the end wall 114 being connected to the end of the first side wall 112 away from the second container body 120.
[0062] For example, the third connecting portion 113 and the first sidewall 112 are connected in a staggered manner, and the third connecting portion 113 and the first sidewall 112 together define a step 119 inside the first container body 101.
[0063] For example, the third connecting portion 113 is connected to the mounting housing 150. For example, the third connecting portion 113 and the mounting housing 150 are connected by a thread. For instance, the outer surface of the third connecting portion 113 is provided with a third thread 118, and the mounting housing 150 is provided with a fourth thread 155, and the third thread 118 and the fourth thread 155 are connected.
[0064] For example, the mounting shell 150 covers the third connecting portion 113, and the mounting shell 150 abuts against the end of the first sidewall 112 away from the second container body 120. The outer surface of the mounting shell 150 and the outer surface of the first sidewall 112 transition smoothly, such as the outer surface of the mounting shell 150 and the outer surface of the first sidewall 112 being flush. Or, the outer surfaces of the mounting shell 150 and the first container body 101 are coplanar and transition smoothly.
[0065] For example, the thickness of the end wall 114 is less than the thickness of the first side wall 112.
[0066] For example, the thickness of the third connecting portion 113 is less than or equal to the thickness of the first sidewall 112. For example, the third connecting portion 113 and the first sidewall 112 are misaligned.
[0067] The mounting housing 150 has multiple heat dissipation holes 151, and the heat dissipation component 140 can dissipate the heat from the cooling component 130 to the outside, such as the outside of the mounting housing 150, through the heat dissipation holes 151.
[0068] The mounting housing 150 includes an end wall 152 and a third side wall 153, which are connected, such as being integrally formed. For example, a plurality of heat dissipation holes 151 are spaced apart on the third side wall 153, such as the heat dissipation holes 151 surrounding the third side wall 153, and the heat dissipation holes 151 surrounding the heat dissipation assembly 140. For example, a charging connector 180 is mounted on the third side wall 153.
[0069] In other alternative embodiments, the end wall 152 is also provided with one or more heat dissipation holes.
[0070] It should be understood that, while maintaining the strength of the mounting shell 150, the number and size of the heat dissipation holes 151 can be set according to actual needs, and this application embodiment does not impose any limitations.
[0071] The mounting housing 150 further includes a fourth connecting portion 154, which is connected to the third sidewall 153 and located at the end of the third sidewall 153 away from the end wall 152. A fourth thread 155 is provided on the inner surface of the fourth connecting portion 154. The fourth connecting portion 154 is connected to the third connecting portion 113, and the fourth connecting portion 154 encloses or surrounds the third connecting portion 113. The fourth connecting portion 154 abuts against the first sidewall 112, and the outer surface of the fourth connecting portion 154 smoothly transitions to the outer surface of the first sidewall 112.
[0072] For example, the thickness of the fourth connection portion 154 gradually increases from one end away from the end wall 152 to the other end to increase the connection stability between the mounting shell 150 and the first container body 101.
[0073] In other alternative embodiments, the mounting housing 150 further includes a limiting platform connected to the inner surface of the third sidewall 153 and located below the fourth thread 155. The limiting platform is used to limit the end wall 114, which can fit against the limiting platform. Exemplarily, the mounting housing 150 also includes a cooling hole formed on the limiting platform, through which at least a portion of the cooling portion 131 of the cooling assembly 130 can be exposed and contact the end wall 114.
[0074] For example, a portion of the cooling assembly 130 is disposed within the cooling hole, the cooling portion 131 is flush with the surface of the limiting platform, and the end wall 114 is attached to the cooling portion 131 and the limiting platform.
[0075] In other alternative embodiments, the cooling portion 131 can protrude from the limiting platform, and correspondingly, the end wall 114 can be provided with a groove to accommodate the cooling portion 131 while maintaining contact with the cooling portion 131.
[0076] In other alternative embodiments, the cooling part 131 may be located inside the cooling hole, or the cooling part 131 may be located below the limiting platform, and a protruding part may be provided below the end wall 114, which may be placed inside the cooling hole and contact the cooling part 131.
[0077] Please continue reading. Figures 1 to 3 The refrigeration container 100 also includes a liquid dispensing control head 190, which is mounted on the mounting housing 150 and communicates with the first receiving cavity 115 of the first container body 101. A user can operate the liquid dispensing control head 190 to dispense liquids such as beer from within the first container body 101.
[0078] Please continue reading. Figures 1 to 3 The refrigeration container 100 also includes a top cover 160, which is detachably mounted on the top of the second container body 120 and covers the opening 124 when mounted on the second container body 120.
[0079] It should be noted that the arrangement relationship between the second container body 120 and the first container body 101 in this embodiment is not limited to the height direction D1 of the refrigeration container 100, but can also be arranged in other directions, such as the transverse direction, which is perpendicular to the height direction D1 of the refrigeration container 100.
[0080] In other alternative embodiments, in order to further enhance the sealing performance of the connection between the first container body 101 and the second container body 120, a sealing sleeve may be fitted on the outer surface of the first container body 101 and the second container body 120.
[0081] Please continue reading. Figures 1 to 3The refrigeration container 100 also includes a detection component 102, which is used to detect information about the beer inside the first container body 101, such as temperature information and the amount of beer. An example is given below.
[0082] For example, the detection component 102 can detect the amount of liquid, such as beer, in the first container body 101. When the detection component 102 detects that the amount of beer in the first container body 101 has dropped to a preset amount, the detection component 102 sends a control signal indicating insufficient beer to control the cooling component 130 and the heat dissipation component 140 to stop working. Furthermore, the cooling container 100 may also include an indicator. When the indicator receives the control signal indicating insufficient beer from the detection component 102, the indicator can issue a prompt message, such as emitting a prompt sound, to inform the user to add beer.
[0083] For example, the detection component 102 can detect the temperature of the liquid, such as beer, inside the first container body 101. When the detection component 102 detects that the beer temperature inside the first container body 101 has reached a preset temperature, the detection component 102 sends a control signal indicating that the beer temperature has reached the preset temperature to control the cooling component 130 and the heat dissipation component 140 to stop working. Conversely, when the detection component 102 detects that the beer temperature inside the first container body 101 has not reached the preset temperature, the detection component 102 sends a control signal indicating that the beer temperature has not reached the preset temperature to control the cooling component 130 and the heat dissipation component 140 to work.
[0084] The detection component 102 may include one or more sensors, such as a temperature sensor.
[0085] Other structures of the container body of the refrigeration container are described below with reference to other accompanying drawings.
[0086] like Figures 4 to 6 As shown, Figures 4 to 6 The differences between the refrigeration container 200 and the refrigeration container 100 include at least the following: the first container body 210 and the second container body 220 in the refrigeration container 200 are joined and sealed along the circumferential direction D2 of the refrigeration container 200 to form the container body 201. The first container body 210 is thermally conductive and may be made of a metal material. The second container body 220 is transparent and may be made of a transparent glass or transparent plastic material. The joining and sealing of the first container body 210 and the second container body 220 can be referenced to the joining and sealing of the first container body 101 and the second container body 120, and will not be described in detail here. It should be noted that the first container body 101 and the second container body 120 can also be formed into the container body 201 using other joining and sealing methods.
[0087] For example, the first container body 210 and the cooling portion of the cooling component 230 are in contact, such as being in contact, or in contact, such as being in contact, or in contact, with the heating portion of the cooling component 230 and the heat dissipation component 240. Thus, when the cooling component 230 is energized, it conducts heat from the alcoholic liquid, such as beer, within the first container body 210 to the heat dissipation component 240. When the heat dissipation component 240 is energized, it dissipates the heat from the cooling component 230 to the outside through the heat dissipation holes 251 of the mounting housing 250. The heat dissipation component 240 and the cooling component 230 are mounted within the mounting housing 250. In this application embodiment, the mounting housing 250, heat dissipation component 240, and cooling component 230 can all be referenced to the mounting housing 150, heat dissipation component 240, and cooling component 130, and will not be described further here.
[0088] For example, the difference between the refrigeration container 200 and the refrigeration container 100 also includes that both the first container body 210 and the second container body 220 are connected to the mounting shell 250, such as by a threaded connection. The specific connection relationship between the first container body 210 and the second container body 220 and the mounting shell 250 can be referred to the connection relationship between the first container body 101 and the mounting shell 150, and will not be repeated here.
[0089] Other components in the refrigeration container 200, such as the power connector 280, the liquid outlet control head 290, the top cover 260, and the detection component 202, can refer to other components in the refrigeration container 100, such as the power connector 180, the liquid outlet control head 190, the top cover 160, and the detection component 102. The embodiments of this application will not be described in detail here.
[0090] It should be noted that in this embodiment, the first container body 210 and the second container body 220 are sealed together along the circumferential direction D2 of the refrigeration container 200. The first container body 210 has a first receiving cavity 215, and the second container body 220 has a second receiving cavity 223. The first receiving cavity 215 and the second receiving cavity 223 together form the receiving cavity 203. When the first receiving cavity 215 and the second receiving cavity 223 jointly contain alcoholic liquids such as beer, the alcoholic liquids such as beer in the first receiving cavity 215 and the second receiving cavity 223 are closer to the refrigeration component 230 than the alcoholic liquids such as beer in the first receiving cavity 115 and the second receiving cavity 123. Therefore, compared with the refrigeration container 100, the refrigeration uniformity of the alcoholic liquids such as beer in the refrigeration container 200 is better, and the cooling rate of the alcoholic liquids such as beer in the refrigeration container 100 is faster.
[0091] Furthermore, the user can view the state of the alcoholic beverage inside container 101 through the transparent second container body 120, and the user can view the state of the alcoholic beverage inside container 201 through the transparent second container body 220. In comparison, the user can basically only view the state inside the second container body 120 through the second container body 120, while the user can view the state inside both the second container body 220 and the first container body 210 through the second container body 220.
[0092] like Figures 7 to 9 As shown, Figures 7 to 9 The differences between the refrigeration container 300 and the refrigeration container 100 or refrigeration container 200 include at least the following: the container body 301 in the refrigeration container 300 is a structural component, and the container body 301 is thermally conductive, such as the container body 301 being made of metal.
[0093] For example, the container body 301 and the cooling portion of the cooling component 330 are in contact, such as being in contact, or in contact, such as being in contact, or in contact, with the heating portion of the cooling component 330 and the heat dissipation component 340. Thus, when the cooling component 330 is energized, it conducts heat from the alcoholic liquid, such as beer, inside the container body 301 to the heat dissipation component 340. When the heat dissipation component 340 is energized, it dissipates the heat from the cooling component 330 to the outside through the heat dissipation holes 351 of the mounting housing 350. The heat dissipation component 340 and the cooling component 330 are mounted inside the mounting housing 350. In this embodiment, the mounting housing 350, heat dissipation component 340, cooling component 330, and detection component 302 can all be referenced to the mounting housing 150, heat dissipation component 240, cooling component 130, and detection component 102, and will not be described again here.
[0094] The container body 301 and the mounting shell 350 are connected, for example, by a threaded connection. The specific connection method between the container body 301 and the mounting shell 350 can be referred to the connection relationship between the first container body 101 and the mounting shell 150, and will not be repeated here.
[0095] Other components in the refrigeration container 200, such as the power connector 280, the liquid outlet control head 290, and the top cover 260, can refer to other components in the refrigeration container 100, such as the power connector 180, the liquid outlet control head 190, and the top cover 160. The embodiments of this application will not be described in detail here.
[0096] It should be noted that the container body 301 in this embodiment is entirely made of metal, such as being integrally molded. In practical applications, the container body 301 has thermal conductivity. Compared to container bodies 101 and 201, the cooling effect of the refrigeration container 300 on the liquid such as beer contained in the cavity 303 of the container body 301 is much greater for the liquid contained in the cavity 303 than for the refrigeration containers 100 and 200. However, in practical applications, because the container body 301 is made of metal, it is not transparent, which makes it difficult for users to see the state of the liquid contained in the cavity 303 of the container body 301.
[0097] To allow users to easily observe the state of the container body 301's receiving cavity 303 if it contains alcoholic liquid, a hole structure can be formed in the container body 301, and a transparent component can be embedded in the hole structure. The following description, in conjunction with other accompanying drawings, provides an example.
[0098] like Figure 10 As shown, Figure 10 The difference between the refrigeration container 400 and the refrigeration container 300 includes: a transparent component 404 is embedded in the container body 401 of the refrigeration container 400. The transparent component 404 is disposed in the height / vertical direction of the refrigeration container 300 and is generally elongated. For example, the transparent component 404 is located between the top cover 460 and the mounting shell 450, and the transparent component 404 is spaced apart from the top cover 460 and the mounting shell 450, that is, the transparent component 404 is not connected to either the top cover 460 or the mounting shell 450.
[0099] For example, the minimum distance between the transparent component 404 and the top cover 460 is greater than the minimum distance between the transparent component 404 and the mounting housing 450.
[0100] It should be understood that the transparent component 404 in this embodiment has transparent properties, such as being made of transparent plastic or transparent glass. The container body 401 in this embodiment has thermal conductivity, such as being made of metal. This allows the user to observe the liquid level and condition of the beverage inside the container body 401 through the transparent component 404.
[0101] It should also be understood that, in the embodiments of this application, after the transparent component 404 is embedded in the container body 401, the connection position between the transparent component 404 and the container body 401 is sealed.
[0102] like Figure 11 As shown, Figure 11The differences between the refrigeration container 600 and the refrigeration container 100 shown include at least the following: the refrigeration assembly 630 adopts a compressor refrigeration structure, the refrigeration part 631 is an evaporator, the heating part 632 is a condenser, and the refrigeration assembly 630 also includes a compressor 633 and a throttle 634. The evaporator, condenser, compressor 633 and throttle 634 are installed through pipes and are all installed in the mounting shell 650.
[0103] The container body 601 has an end wall 614 and a side wall 616 surrounding the end wall 614. The end wall 614 and the side wall 616 enclose a receiving cavity 615. The end wall 614 is made of a thermally conductive material, such as metal. The end wall 614 can be located at the top or bottom of the receiving cavity 615. The accompanying drawings only show the case where the end wall 614 is located at the bottom of the receiving cavity 615.
[0104] The refrigeration container 600 also includes a mounting shell 650, which is connected to the end wall 614 or the side wall 616. The refrigeration component 630 and the heat dissipation component 640 are both disposed inside the mounting shell 650, and the refrigeration component 631 is close to or mounted on the end wall 614.
[0105] Furthermore, as shown in the appendix Figure 12 and 13 As shown, the condenser can adopt a vortex tube design and be attached to the end wall 614, resulting in a larger contact area between the condenser and the end wall 614 and higher cooling efficiency. Understandably, the condenser can also adopt a spiral tube design, as shown in the attached diagram. Figure 14 As shown, the condenser can extend into the receiving cavity 615. The condenser penetrates the end wall 614 and connects to the compressor 633 and the throttle 634 below the end wall 614 (a sealed design is used between the condenser and the end wall). At this point, the condenser directly cools the solution in the receiving cavity 615 without needing to conduct heat through the end wall 614. Furthermore, the spiral tubular design of the condenser increases the surface area with the solution, improving cooling efficiency. The top of the spiral tubular condenser can extend to the middle or the top of the receiving cavity.
[0106] The heat dissipation assembly 640 includes several heat sinks 641 and a fan 642. The evaporator portion is attached to the end wall 614 of the receiving cavity 615 or extends directly into the receiving cavity 615 through the end wall 614. In this case, the end wall 614 can be located at either the top or bottom of the receiving cavity 615. The heat sinks 641 are distributed parallel and spaced apart on the condenser. The fan 642 is located beside the condenser and is used to blow air onto the condenser. The mounting housing 650 is provided with corresponding air inlet holes 651 and heat dissipation holes 652. The air blown by the fan 642 is directed towards the heat dissipation holes 652 and circulates to the outside, while fresh air enters through the corresponding air inlet holes 651.
[0107] In addition, it can also be attached as follows Figure 15 As shown, a heat-conducting component 500 can also be provided. The heat-conducting component 500 is cylindrical and extends into the receiving cavity 101a and is installed on the end wall 614. The heat-conducting component 500 is hollow, and the condenser is placed inside the heat-conducting component 500 to improve the cooling efficiency of the heat-conducting component 500. In other embodiments, the condenser can also be designed with a spiral tube structure and wound around the outside of the heat-conducting component 500 to increase the cooling area using the heat-conducting component 500.
[0108] like Figures 16 to 21 As shown in the illustration, this application also provides a refrigeration container 100, including a container body 101, which has a receiving cavity 101a. The refrigeration container 100 further includes a heat-conducting component 500. The heat-conducting component 500 is installed in the container body 101 and / or the mounting shell 150; that is, the heat-conducting component 500 can be installed in the container body 101, or in the mounting shell 150, or in both the container body 101 and the mounting shell 150.
[0109] The heat-conducting component 500 has thermal conductivity, meaning it can conduct heat. For example, the heat-conducting component 500 may be made of metal.
[0110] For example, the heat-conducting component 500 can have a solid structure, such as a cylindrical structure. In other alternative embodiments, the heat-conducting component 500 can also be a frustum or a cone structure. It should be understood that the heat-conducting component 500 can also be other columnar structures, and the embodiments of this application do not limit the shape of the heat-conducting component 500.
[0111] In other alternative embodiments, the heat-conducting component 500 is not limited to a solid structure. For example, in order to save materials, the heat-conducting component 500 has a cavity structure inside. It should be noted that in order to prevent alcoholic liquids such as beer located in the receiving cavity 111 from entering the cavity inside the heat-conducting component 500, the cavity of the heat-conducting component 500 is sealed by the heat-conducting component 500.
[0112] At least a portion of the heat-conducting component 500 is disposed within the receiving cavity 101a. The heat-conducting component 500 can at least pass through the container body 101 so that its bottom end 502 contacts the cooling component 131, or in other words, the heat-conducting component 500 can at least pass through the container body 101 and abut against the cooling component 131. Thus, the cooling assembly 130 can conduct the heat of the alcoholic liquid, such as beer, contained in the receiving cavity 101a to the heat dissipation assembly 140 through the heat-conducting component 500, and the heat dissipation assembly 140 can dissipate the heat from the cooling assembly 130 to the outside. For example, when the cooling assembly 130 is energized, it conducts the heat of the liquid, such as beer, contained in the receiving cavity 101a to the heat dissipation assembly through the heat-conducting component 500.
[0113] The top end 501 of the heat-conducting component 500 is close to the opening 101b of the container body 101.
[0114] For example, the heat-conducting component 500 is sealed to the container body 101 and / or the mounting shell 150, that is, the heat-conducting component 500 is sealed to the container body 101, or the heat-conducting component 500 is sealed to the mounting shell 150, or the heat-conducting component 500 is sealed to both the container body 101 and the mounting shell 150. Figure 16 and Figure 17 As shown, this application embodiment takes the sealed connection between the heat-conducting component 500 and the container body 101 as an example for explanation. The sealed connection between the heat-conducting component 500 and the mounting shell 150 will be explained below with reference to other drawings.
[0115] Please continue reading. Figures 16 to 17 The container body 101 may include a connected first end wall 114 and a first side wall 112, such as the first end wall 114 and the first side wall 112 being integrally formed. It should be understood that the first end wall 114 is connected to the bottom of the first side wall 112. The heat-conducting component 500 passes through at least the first end wall 114 of the container body 101 such that its bottom end 502 contacts the cooling section 131. In embodiments of this application, the heat-conducting component 500 and the first end wall 114 are sealed together.
[0116] For example, the container body 101 includes a mounting hole 114a formed on the first end wall 114, and the mounting hole 114a communicates with the receiving cavity 101a. It should be noted that when the container body 101 is connected to the mounting shell 150, the mounting hole 114a can expose at least partially the cooling portion 131 of the cooling assembly 130, or the cooling portion 131 of the cooling assembly 130 can be exposed at least partially through the mounting hole 114a.
[0117] Mounting hole 114a allows the bottom end 502 of the heat-conducting component 500 to pass through, or in other words, the bottom end 502 of the heat-conducting component 500 is mounted in mounting hole 114a and contacts the cooling part 131. It should be understood that mounting hole 114a is adapted to the shape and size of the heat-conducting component 500 to facilitate a sealed connection between the first end wall 114 and the heat-conducting component 500.
[0118] It should be understood that the sealed connection between the heat-conducting component 500 and the first end wall 114 can prevent leakage at the mounting hole 114a.
[0119] For example, the sealing connection between the heat-conducting component 500 and the first end wall 114 includes a sealing ring 170a connecting the heat-conducting component 500 and the first end wall 114. It should be understood that the sealing connection between the heat-conducting component 500 and the first end wall 114 is not limited to the sealing ring 170a. One of the heat-conducting component 500 and the first end wall 114 may have a sealing groove 171, the sealing ring 170a may be installed within the sealing groove 171, and the other of the heat-conducting component 500 and the first end wall 114 may press against the sealing ring 170a. This achieves a sealing connection between the heat-conducting component 500 and the first end wall 114.
[0120] To facilitate the creation of the sealing groove 171, in this embodiment of the application, the sealing groove 171 is formed in the first end wall 114. Exemplarily, the container body 101 also includes a reinforcing structure 1141 disposed on the first end wall 114. The reinforcing structure 1141 is located on the side of the first end wall 114 away from the refrigeration assembly 130, and surrounds the mounting hole 114a. The reinforcing structure 1141 and the first end wall 114 together define the sealing groove 171, and the reinforcing structure 1141 surrounds the sealing ring 170a.
[0121] It should be noted that containers often have thin walls, and directly creating a groove structure on the container wall can easily lead to a decrease in container stability. However, the sealing groove 171 in this embodiment is defined by the first end wall 114 and the reinforcing structure 1141 disposed on the first end wall 114, which can improve the sealing performance of the connection between the first end wall 114 and the heat-conducting component 500 while ensuring the strength of the first end wall 114.
[0122] For example, the sealing ring 170a has certain deformation characteristics. When the sealing ring 170a is subjected to external forces such as the compression of the heat-conducting component 500, the sealing ring 170a will undergo a small amount of deformation, which can further improve the effect of sealing the connection position between the heat-conducting component 500 and the first end wall 114.
[0123] It should be noted that the sealing connection between the first end wall 114 and the heat-conducting component 500 is not limited to the use of a sealing ring 170a between the first end wall 114 and the heat-conducting component 500. In other alternative embodiments, the first end wall 114 and the heat-conducting component 500 are bonded together with adhesive.
[0124] For example, the bottom end 502 of the heat-conducting component 500 is flush with the outer surface of the first end wall 114.
[0125] For example, the bottom end 502 of the heat-conducting component 500 is attached to the cooling component 131.
[0126] For example, the diameter of the heat-conducting component 500 is approximately the same as the diameter of the cooling component 131, and the bottom end 502 of the heat-conducting component 500 and the cooling component 131 are approximately completely in contact.
[0127] The portion of the heat-conducting component 500 located within the receiving cavity 101a is spaced apart from the first sidewall 112 of the container body 101.
[0128] For example, the mounting housing 150 also includes a second end wall 154 and a second side wall 153, the second end wall 154 and the second side wall 153 are connected, the second side wall 153 surrounds the periphery of the second end wall 154, and the second end wall 153 is provided with one or more heat dissipation holes.
[0129] like Figure 18 As shown, this application embodiment also provides a refrigeration container 200, wherein the heat-conducting component 500a of the refrigeration container 200 at least passes through the limiting platform 204 in the refrigeration container 200 and contacts the refrigeration part of the refrigeration assembly 230, and the heat-conducting component 500a is at least sealed to the limiting platform 204.
[0130] For example, the limiting platform 204 has a cooling hole 2041 through which at least part of the cooling portion of the cooling assembly 130 is exposed. The bottom end of the heat-conducting component 500a passes through the container body 210 and the cooling hole 2041 of the limiting platform 204 and contacts the cooling portion of the cooling assembly 230. The heating portion of the cooling assembly 230 contacts the heat dissipation assembly 240, so that the heat-conducting component 500a can conduct heat from the alcoholic liquid, such as beer, contained in the container body 210 to the cooling assembly 230, and the heat dissipation assembly 240 can dissipate the heat from the cooling assembly 230 to the outside.
[0131] The shape of the heat-conducting component 500a can be referenced from that of the heat-conducting component 500, and will not be described in detail here.
[0132] In one embodiment, the heat-conducting component 500a can pass through the container body 210 by having an opening at the bottom of the container body 210, with the opening at the bottom of the container body 210 opposite to the opening at the top of the container body 210. The heat-conducting component 500a can be inserted into the cooling hole 2041 through the bottom opening of the container body 210. In other optional embodiments, the container body 210 can have a side wall 214 and an end wall connected to the side wall 214, with a mounting hole in the end wall. The heat-conducting component 500a can pass through the mounting hole of the container body 210 and be inserted into the cooling hole 2041. The side wall 214 can be referred to as the first side wall 112, and will not be described in detail here. The end wall and mounting hole of the container body 210 can be referred to as the first end wall 114 and the mounting hole 114a, and will not be described in detail here. The top opening of the container body 210 can be referred to as the opening 101b, and will not be described in detail here.
[0133] For example, the heat-conducting component 500a is only sealed to the limiting platform 204. After the heat-conducting component 500a and the limiting platform 204 are sealed together, the limiting platform 204 can be installed on the mounting shell 150a. In other alternative embodiments, after the heat-conducting component 500a and the limiting platform 204 are sealed together, the limiting platform 204 can also be installed on the bottom of the container body 210. The sealing connection method between the heat-conducting component 500a and the limiting platform 204 can be referred to the above embodiments, and will not be repeated here.
[0134] In other alternative embodiments, the heat-conducting component 500a is sealed to both the limiting platform 204 and the container body 210. It should be noted that the sealing connection method between the heat-conducting component 500a and the container body 210 can refer to the above embodiments and will not be repeated here. It should be understood that when the heat-conducting component 500a is sealed to both the limiting platform 204 and the container body 210, the end walls of the limiting platform 204 and the container body 210 can fit together.
[0135] For example, the limiting platform 204 is made of a non-thermally conductive material, such as plastic. In other alternative embodiments, the thermally conductive component 500a and the limiting platform 204 are integrally formed.
[0136] like Figures 19 to 21 As shown, this embodiment provides a refrigeration container 300. A refrigeration component 330 and a heat dissipation component 340 in the refrigeration container 300 are installed in a mounting shell 150b, which is located at the top of the refrigeration container 300. The top end 501b of the heat-conducting component 500b of the refrigeration container 300 contacts, or is attached to, the refrigeration portion 331 of the refrigeration component 330 installed in the mounting shell 150b.
[0137] The heat-conducting component 500b is connected to the mounting housing 150b. Exemplarily, the mounting housing 150b includes a connected first end wall 362 and a first side wall 364, with the first side wall 364 connected to the periphery of the first end wall 362. The heat-conducting component 500b is connected to the first end wall 362. Exemplarily, the mounting housing 150b also includes a mounting hole 365 formed in the first end wall 362, with the cooling portion 331 at least partially exposed through the mounting hole 365. The top end 501b of the heat-conducting component 500b is mounted in the mounting hole 365 and contacts the cooling portion 331.
[0138] At least a portion of the heat-conducting component 500b is disposed within the receiving cavity 311 of the container body 310, and the bottom end 502b of the heat-conducting component 500b is located within the receiving cavity 311, such as the bottom end 502b of the heat-conducting component 500b being close to the bottom of the container body 310. For example, the container body 310 includes a connected second end wall 312 and a second side wall 314, the second side wall 314 being connected to the periphery of the second end wall 312. The bottom end 352 of the heat-conducting component 500b is close to the second end wall 312.
[0139] In this configuration, the heating elements 332 of the heat dissipation component 340 and the cooling component 330 are in contact. This allows the cooling component 330 to conduct heat from the liquid (e.g., beer) contained in the receiving cavity 311 to the heat dissipation component 340 via the heat-conducting component 500b. The heat dissipation component 340 then dissipates the heat from the cooling component 330 to the outside. For example, when energized, the cooling component 330 conducts heat from the liquid (e.g., beer) contained in the receiving cavity 311 to the heat dissipation component 340 via the heat-conducting component 500b, and the heat dissipation component 340 dissipates the heat from the cooling component 330 to the outside.
[0140] For example, the mounting housing 150b has a plurality of heat dissipation holes 361, and the heat dissipation assembly 340 can dissipate heat from the cooling assembly 330 to the outside, such as the outside of the mounting housing 150b, through the heat dissipation holes 361. The plurality of heat dissipation holes 361 are spaced apart on the first sidewall 364, and the heat dissipation holes 361 are arranged around the heat dissipation assembly 340.
[0141] In other alternative embodiments, the mounting housing 150b further includes a top wall 368 connected to a first side wall 364. The top wall 368 and the first end wall 362 are located on the upper and lower sides of the first side wall 364, respectively, to form a cavity for accommodating the cooling assembly 330 and the heat dissipation assembly 340. Exemplarily, the top wall 368 also has one or more heat dissipation holes.
[0142] The container body 310 has an opening 315. The mounting shell 150b is detachably mounted on the top of the container body 310 and covers the opening 315 when mounted on the container body 310. The mounting hole 365 communicates with the opening 315 to facilitate the placement of a portion of the heat-conducting component 500b into the receiving cavity 311 after the heat-conducting component 500b is connected to the first end wall 362.
[0143] For example, the heat-conducting component 500b and the first end wall 362 are sealed together, such as by a sealing ring 370 connecting the heat-conducting component 500b and the first end wall 362. It should be understood that the sealing connection between the heat-conducting component 500b and the first end wall 362 is not limited to the sealing ring 370. One of the heat-conducting component 500b and the first end wall 362 may have a sealing groove 3661, within which the sealing ring 370 is installed, and the other of the heat-conducting component 500b and the first end wall 362 presses against the sealing ring 370. This achieves a sealed connection between the heat-conducting component 500b and the first end wall 362, preventing liquids such as beer from entering the mounting housing 150b from the connection point between the heat-conducting component 500b and the first end wall 362, thus protecting the devices within the mounting housing 150b, such as the heat dissipation assembly 340 and the cooling assembly 330.
[0144] For example, the mounting housing 150b also includes a reinforcing structure 366 disposed on the first end wall 362. The reinforcing structure 366 is located on the side of the first end wall 362 away from the cooling assembly 330 and surrounds the mounting hole 365. The reinforcing structure 366 and the first end wall 362 together define a sealing groove 3661. A sealing ring 370 is installed in the sealing groove 3661 and the reinforcing structure 366 surrounds the sealing ring 370.
[0145] For example, the top end 351 of the heat-conducting component 500b is flush with the inner surface of the first end wall 362.
[0146] For example, the top end 351 of the heat-conducting component 500b is attached to the cooling component 331.
[0147] For example, the diameter of the heat-conducting component 500b is approximately the same as the diameter of the cooling component 331, and the top end 351 of the heat-conducting component 500b and the cooling component 331 are approximately in complete contact.
[0148] The portion of the heat-conducting component 500b located within the receiving cavity 311 is spaced apart from the first sidewall 314 of the container body 310.
[0149] For example, the heat-conducting component 500b can have a solid structure, such as a cylindrical structure. In other alternative embodiments, the heat-conducting component 500b can also be a frustum or a cone structure. It should be understood that the heat-conducting component 500b can also be other columnar structures, and the embodiments of this application do not limit the shape of the heat-conducting component 500b.
[0150] In other alternative embodiments, the heat-conducting component 500b is not limited to a solid structure. For example, in order to save materials, the heat-conducting component 500b has a cavity structure inside. It should be noted that in order to prevent alcoholic liquids such as beer located in the receiving cavity 311 from entering the cavity inside the heat-conducting component 500b, the cavity of the heat-conducting component 500b is sealed by the heat-conducting component 500b.
[0151] For example, when the mounting shell 150b is mounted on the container body 310, the second sidewall 314 supports the first sidewall 364, or the second sidewall 314 supports the first sidewall 364 and the first endwall 362, and the outer surface of the second sidewall 314 and the outer surface of the first sidewall 364 are smoothly transitioned, such as flush.
[0152] For example, the mounting housing 150b also includes a limiting portion 363, which is connected to the outer surface of the first end wall 362. The limiting portion 363 protrudes from the outer surface of the first end wall 362 and is close to the first side wall 364. When the mounting housing 150b is mounted on the container body 310, the limiting portion 363 is installed in the receiving cavity 311 from the opening 315, and the limiting portion 363 is adjacent to the second side wall 314.
[0153] For example, the thickness of the limiting portion 363 gradually increases from one end away from the first end wall 364 to the other end, and the limiting portion 363 can increase the installation stability between the mounting shell 150b and the container body 310.
[0154] For example, the base 320 of the refrigeration container 300 supports the container body 310, and the base 320 and the container body 310 are connected. For example, the container body 310 also includes a first connecting portion 316, which connects a second end wall 312 and a second side wall 314. The base 320 includes a connected seat body 321 and a second connecting portion 322, and the first connecting portion 316 and the second connecting portion 322 are connected, such as by a threaded connection.
[0155] For example, the first connecting portion 316 and the second sidewall 314 are connected in a staggered manner, such that the first connecting portion 316 and the second sidewall 314 together define a step 318. It should be noted that the space surrounded by the first connecting portion 316 is smaller than the space surrounded by the second sidewall 314. For example, the diameter of the first connecting portion 316 is smaller than the diameter of the first sidewall 314.
[0156] For example, the second connecting portion 322 surrounds the first connecting portion 316 and abuts against the second sidewall 314. The outer surface of the second connecting portion 322 and the outer surface of the second sidewall 314 transition smoothly, such as being flush.
[0157] The detection component 302, power connector 380, and liquid outlet control head 390 of the refrigeration container 300 can all be referenced. Figures 1 to 3 The cold wine container 100 shown here will not be described in detail here.
[0158] The refrigeration container provided in the embodiments of this application has been described in detail above. Specific examples have been used to illustrate the principle and implementation of this utility model. The description of the above embodiments is only for the purpose of helping to understand the method and core idea of this utility model. At the same time, for those skilled in the art, there will be changes in the specific implementation and application scope based on the idea of this application. Therefore, the content of this specification should not be construed as a limitation of this application.
Claims
1. A refrigeration container, characterized in that, include: A container body having a receiving cavity for containing liquid, and at least a portion of the container body being heat-conducting; The container body has an end wall and a side wall surrounding the end wall, the end wall and the side wall enclosing the receiving cavity, and the end wall is heat-conducting; Mounting housing, which is connected to the end wall or side wall; A refrigeration assembly, located within a mounting housing, comprising a refrigeration section and a heating section, the refrigeration section being adjacent to or mounted on the end wall for cooling the receiving cavity; the refrigeration assembly further comprising a compressor and a throttle, the refrigeration section being an evaporator and the heating section being a condenser, the compressor connecting the evaporator and the condenser, and the throttle connecting the evaporator and the condenser; wherein the evaporator is vertically distributed and at least partially extends into the receiving cavity, the evaporator having a spiral design; and A heat dissipation assembly is located inside a mounting housing. The heat dissipation assembly includes a plurality of heat sinks and a fan. The plurality of heat sinks are mounted on the condenser, and the fan is used to exhaust air onto the heat sinks. The mounting housing has an air inlet and a heat dissipation hole that run through the same direction, and the fan and the heat sink are both located on the through path of the air inlet and the heat dissipation hole.
2. The refrigeration container according to claim 1, characterized in that, It also includes a heat-conducting component mounted on the container body and at least partially extending into the receiving cavity, with the evaporator distributed on the heat-conducting component.