CN216675476U

CN216675476U - Flow distribution disc, cold tank assembly and water dispenser

Info

Publication number: CN216675476U
Application number: CN202122663086.4U
Authority: CN
Inventors: 耿纪伟; 朱飞; 黄森逢; 何俊森
Original assignee: TCL Home Appliances Zhongshan Co Ltd
Current assignee: TCL Air Conditioner Zhongshan Co Ltd
Priority date: 2021-11-02
Filing date: 2021-11-02
Publication date: 2022-06-07
Anticipated expiration: 2031-11-02

Abstract

The application discloses a distribution plate, a cold tank assembly and a water dispenser, wherein the distribution plate comprises a plate body and a first water outlet pipe; the disc body is used for being installed in the cold tank and dividing the inner cavity of the cold tank into a first cavity and a second cavity which are arranged at intervals; the first water outlet pipe is connected to one side of the plate body and extends towards the direction far away from the plate body, and the first water outlet pipe is used for being connected with the bottom wall of the cold tank to support the plate body; one side of the disc body facing the first water outlet pipe is provided with a first heat insulation layer, and the periphery of the first water outlet pipe is provided with a second heat insulation layer. In this application, through being equipped with first insulating layer in one side of the dish body towards first outlet pipe, the warm water in avoiding first cavity and the cold water in the second cavity take place the heat exchange, is equipped with the second insulating layer through the periphery at first outlet pipe, avoids the warm water in the first outlet pipe and the cold water in the second cavity to take place the heat exchange to promote the thermal-insulated effect of flow divider, solved the problem that the water dispenser takes place the cluster temperature easily.

Description

Flow distribution plate, cold tank assembly and water dispenser

Technical Field

The application belongs to the field of water dispensers, and particularly relates to a flow distribution plate, a cold tank assembly and a water dispenser.

Background

The water dispenser is an indispensable household appliance in daily life. The cold tank structure of the water dispenser on the market at present, heat exchange easily takes place between cold water district and the warm water district, and the temperature problem of cluster is serious, leads to the user can't receive normal atmospheric temperature water, can't satisfy user's user demand.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a flow distribution plate, a cold tank assembly and a water dispenser to promote the heat insulation effect of the flow distribution plate and solve the problem that the existing water dispenser is easy to generate temperature cross.

In a first aspect, an embodiment of the present application provides a diverter plate for mounting to a cold tank of a water dispenser, where the diverter plate includes:

the disc body is used for being installed in the cold tank and dividing the inner cavity of the cold tank into a first cavity and a second cavity which are arranged at intervals; and

the first water outlet pipe is connected to one side of the tray body and extends towards the direction far away from the tray body, and the first water outlet pipe is used for being connected with the bottom wall of the cold tank to support the tray body;

one side of the disc body facing the first water outlet pipe is provided with a first heat insulation layer, and the periphery of the first water outlet pipe is provided with a second heat insulation layer.

Optionally, a ring rib is convexly arranged on one side of the disc body facing the first water outlet pipe, the ring rib surrounds the first water outlet pipe, and the ring rib and the disc body enclose to form the first heat insulation layer.

Optionally, the ring rib is arranged close to the outer circumferential edge of the disc body.

Optionally, the first insulation layer is filled with insulation or air.

Optionally, a heat insulation pipe is connected to one side of the tray body facing the first water outlet pipe, and the heat insulation pipe is sleeved on the periphery of the first water outlet pipe and forms the second heat insulation layer with the first water outlet pipe at an interval.

Optionally, the wall thickness of the heat insulation pipe is gradually decreased from the end connected with the disc body to the end far away from the disc body.

Optionally, the second insulation layer is filled with insulation or air.

Optionally, a sleeve for inserting an ultraviolet lamp is convexly arranged on one side of the tray body facing the first water outlet pipe, the tray body is provided with an opening communicated with the sleeve, and the sleeve is located in the first heat insulation layer.

Optionally, the diverter tray further includes a first sealing plate, and the first sealing plate is connected to one end of the ring rib away from the tray body, so as to seal the first heat insulation layer.

Optionally, a heat insulation member is filled in the first heat insulation layer; or the first heat insulation layer is arranged in a vacuum pumping mode.

In a second aspect, embodiments of the present application further provide a cold tank assembly, including a cold tank and a diverter tray as described in any of the above embodiments, the diverter tray being mounted in the cold tank.

Optionally, the cold tank assembly further comprises a cooling device mounted to the peripheral wall of the second chamber for absorbing heat from the water in the second chamber.

Optionally, a second water outlet pipe communicated with the second chamber is arranged on the bottom wall of the cooling tank, and one end, far away from the disc body, of the first water outlet pipe is connected with the second water outlet pipe.

In a third aspect, an embodiment of the present application further provides a water dispenser, which includes the cold tank assembly described in any one of the above embodiments.

Optionally, the water dispenser further comprises a hot tank;

the bottom wall of the cold tank is provided with a second water outlet pipe communicated with the second cavity, one end of the first water outlet pipe, which is far away from the disc body, is connected with the second water outlet pipe, and the hot tank is connected with the second water outlet pipe through a water supplementing pipe.

In the embodiment of the application, the first heat insulation layer is arranged on one side, facing the first water outlet pipe, of the disc body, so that the disc body is isolated from cold water in the second cavity, heat of normal-temperature water in the first cavity is prevented from being transferred to the cold water in the second cavity through the disc body, and the temperature of the normal-temperature water in the first cavity is prevented from being reduced; the second heat insulation layer is arranged on the periphery of the first water outlet pipe, so that the first water outlet pipe is isolated from cold water in the second cavity, heat of normal-temperature water in the first water outlet pipe is prevented from being transferred to the cold water through the first water outlet pipe, and the temperature of the normal-temperature water in the first water outlet pipe is prevented from being reduced; so, through the thermal-insulated effect of first insulating layer with the second insulating layer, avoided warm water in the first cavity and cold water in the second cavity to take place the heat exchange, promoted the thermal-insulated effect of flow distribution plate for the user can receive the warm water of getting close to the room temperature, satisfies user's user demand, has solved the problem that the water dispenser takes place the cluster temperature easily.

And the first heat insulation layer and the second heat insulation layer are arranged to avoid heat exchange between warm water and cold water, so that the temperature of the cold water in the second chamber is prevented from rising.

Drawings

The technical solutions and advantages of the present application will become apparent from the following detailed description of specific embodiments of the present application when taken in conjunction with the accompanying drawings.

Fig. 1 is a schematic structural diagram of a cold tank assembly according to an embodiment of the present disclosure.

Fig. 2 is a schematic structural view of a diverter tray of the cold tank assembly of fig. 1.

Fig. 3 is a schematic structural diagram of connection between a cold tank assembly and a hot tank of the water dispenser provided by the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The application provides a flow distribution plate, a cold tank assembly and a water dispenser to promote the heat insulation effect of the flow distribution plate and solve the problem that the existing water dispenser is easy to generate heat.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a cold tank assembly 20 provided in the present application, in this embodiment, the diverter tray 10 includes a tray body 11 and a first water outlet pipe 12; the disc body 11 is used for being installed in the cold tank 21 and setting the interior of the cold tank 21 into a first chamber 21a and a second chamber 21b which are arranged at intervals; a first water outlet pipe 12 is connected to one side of the tray body 11 and extends in a direction away from the tray body 11, and the first water outlet pipe 12 is used for being inserted into the second cavity 21 b; a first heat insulation layer 13 is arranged on one side of the disc body 11 facing the first water outlet pipe 12, and a second heat insulation layer 14 is arranged on the periphery of the first water outlet pipe 12.

The cold tank 21 is used for storing drinking water flowing out of a water barrel of the water dispenser, as shown in fig. 1, one end of the cold tank 21 is open, the diverter disc 10 is installed into the cold tank 21 from the open end of the cold tank 21, and the interior of the cold tank 21 is divided into a first chamber 21a and a second chamber 21b which are arranged at an interval up and down. Wherein, the diameter of the outer peripheral wall of the disk body 11 is smaller than that of the inner wall of the cold tank 21, on one hand, the diverter disk 10 is conveniently and smoothly arranged in the cold tank 21; on the one hand, a gap communicating the first chamber 21a and the second chamber 21b is formed between the outer peripheral wall of the disk body 11 and the inner wall of the cold tank 21, and water in the first chamber 21a flows into the second chamber 21b through the gap.

With continued reference to fig. 1, the cold tank assembly 20 further includes a cooling device 22, the cooling device 22 is mounted on the outer peripheral wall of the second chamber 21b, and the cooling device 22 is used for absorbing heat of the water in the second chamber 21b, so that the temperature of the water in the second chamber 21b is reduced to form cold water. The water in the first chamber 21a is normal temperature water, and since the density of the cold water is higher than that of the warm water, there is stratification between the cold water and the warm water, that is, the cold water in the second chamber 21b and the warm water in the first chamber 21a do not flow relatively without being influenced by external force.

In the present embodiment, the cooling device 22 is an evaporator, and the evaporator is disposed around the outer peripheral wall of the second chamber 21b and closely attached thereto so as to sufficiently absorb the heat of the water in the second chamber 21 b.

In order to reduce the power consumption of the water dispenser, the start and stop of the cooling device 22 are determined by the change of the water temperature in the second chamber 21b, specifically, a temperature sensor is further arranged in the second chamber 21b to detect the temperature of cold water in the second chamber 21b, and when the water temperature in the second chamber 21b is reduced to a first preset temperature, the evaporator stops working; when the temperature of the water in the second chamber 21b rises to a second preset temperature, the evaporator is restarted.

Referring to fig. 1, the bottom wall of the cold tank 21 is further connected to a cold water outlet pipe 24 for a user to receive cold water in the second chamber 21b, and when the user receives the cold water to reduce the cold water in the second chamber 21b, the normal temperature water in the first chamber 21a flows into the second chamber 21b through a gap between the disk body 11 and the inner wall of the cold tank 21, so as to replenish water in the second chamber 21 b. It can be understood that, since the gap between the disk body 11 and the inner wall of the cold tank 21 is small, the normal temperature water in the first chamber 21a flows into the second chamber 21b along the gap, so as to avoid large disturbance to the cold water in the second chamber 21b and prevent the temperature stratification of the cold tank 21 from being damaged.

The first water outlet pipe 12 is connected to the bottom wall of the cold tank 21 to support the plate body 11, wherein the first water outlet pipe 12 may be directly connected to the bottom wall of the cold tank 21, or may be indirectly connected to the bottom wall of the cold tank 21 through another connection structure. In this embodiment, referring to fig. 1 and fig. 3, a second water outlet pipe 23 communicated with the second chamber 21b is disposed on the bottom wall of the cold tank 21, and one end of the first water outlet pipe 12 away from the tray body 11 is connected to the second water outlet pipe 23.

As shown in fig. 3, the second water outlet pipe 23 has a first connecting pipe portion (not shown) extending into the second cavity 21b, and a second connecting pipe portion (not shown) located outside the cold tank 21, wherein one end of the first water outlet pipe 12 away from the tray body 11 is hermetically connected with the first connecting pipe portion, and the second connecting pipe portion is used for being hermetically connected with the warm water outlet pipe 40 so as to allow a user to receive warm water.

It can be understood that, according to the second law of thermodynamics, heat is always transferred from a place where the temperature is high to a place where the temperature is low, by providing the first thermal insulation layer 13 on the side of the disk body 11 facing the first water outlet pipe 12 so that the disk body 11 is isolated from the cold water in the second chamber 21b, the heat of the normal-temperature water in the first chamber 21a is prevented from being transferred to the cold water in the second chamber 21b through the disk body 11, and thus the temperature of the normal-temperature water in the first chamber 21a is prevented from being lowered; the second heat insulation layer 14 is arranged on the periphery of the first water outlet pipe 12, so that the first water outlet pipe 12 is isolated from the cold water in the second cavity 21b, the heat of the normal-temperature water in the first water outlet pipe 12 is prevented from being transferred to the cold water through the first water outlet pipe 12, and the temperature of the normal-temperature water in the first water outlet pipe 12 is prevented from being reduced; therefore, through the heat insulation effect of the first heat insulation layer 13 and the second heat insulation layer 14, the heat exchange between the warm water in the first cavity 21a and the cold water in the second cavity 21b is avoided, the heat insulation effect of the diverter disc 10 is improved, a user can receive the warm water close to the room temperature, the use requirement of the user is met, and the problem that the water dispenser is prone to temperature cross is solved.

In addition, the first heat insulation layer 13 and the second heat insulation layer 14 are arranged to prevent the warm water in the first chamber 21a and the cold water in the second chamber 21b from exchanging heat, and prevent the temperature of the cold water in the second chamber 21b from rising, compared with the existing water dispenser, the cold water can be kept at a lower temperature for a long time, so that the working time of the cooling device 22 is reduced, namely the refrigeration cycle of the water dispenser is shortened, the power consumption of the water dispenser is reduced, and the expenditure is saved for users.

The first thermal insulation layer 13 may be an air layer formed by providing a cavity structure on one side of the disk body 11, or a structural layer made of a material with a small thermal conductivity coefficient and connected to one side of the disk body 11. I.e. the first insulating layer 13 is filled with insulation or air, and likewise the second insulating layer 14 is filled with insulation or air.

It will be appreciated that to further enhance the thermal insulation of the diverter tray 10, the diverter tray 10 itself may be made of a material having a relatively low thermal conductivity.

Referring to fig. 3, in an embodiment of the present application, the water dispenser further includes a hot tank 30; the bottom wall of the cold tank 21 is provided with a second water outlet pipe 23 communicated with the second cavity 21b, one end of the first water outlet pipe 12 far away from the disc body 11 is connected with the second water outlet pipe 23, and the hot tank 30 is connected with the second water outlet pipe 23 through a water supplementing pipe 31.

Specifically, a tee joint is arranged at a second connecting pipe part of the second water outlet pipe 23, the hot tank 30 is connected with the tee joint through a water replenishing pipe 31, the normal-temperature water in the first cavity 21a flows into the hot tank 30 through the first water outlet pipe 12, the second water outlet pipe 23 and the water replenishing pipe 31, the hot tank 30 is provided with a heating device, the heating device is used for heating the normal-temperature water flowing into the hot tank 30 to form hot water, and the hot tank 30 is further connected with a hot water outlet pipe 32 for a user to receive and take the hot water.

It can be understood that the temperature of the warm water in the first cavity 21a is prevented from being reduced by the arrangement of the first heat insulation layer 13, and the heat exchange between the warm water in the first water outlet pipe 12 and the cold water in the second cavity 21b is avoided by the arrangement of the second heat insulation layer 14, so that the temperature of the warm water flowing into the hot tank 30 is close to the room temperature, compared with the existing water dispenser, the temperature of the water flowing into the hot tank 30 is higher, the heating time of the heating device for heating the water to the third preset temperature is reduced, that is, the heating period of the water dispenser is shortened, and the power consumption of the water dispenser is reduced.

Referring to fig. 1 and fig. 2, in an embodiment of the present application, a ring rib 15 is protruded from a side of the tray body 11 facing the first water outlet pipe 12, the ring rib 15 is disposed around the first water outlet pipe 12, and the ring rib 15 and the tray body 11 enclose to form the first heat insulation layer 13.

Specifically, when the drinking water bucket is placed on the water dispenser, the normal temperature water in the bucket flows into the cold tank 21, the normal temperature water firstly flows into the first cavity 21a and flows into the second cavity 21b through the gap between the disk body 11 and the inner wall of the cold tank 21, meanwhile, the air in the second cavity 21b is extruded and discharged under the normal temperature water, when the water in the second cavity 21b is filled to the liquid level and contacts with the bottom of the ring rib 15, the water seals the space formed by the ring rib 15 and the disk body 11 in a liquid sealing mode, namely, the water seals the first heat insulation layer 13 in a liquid sealing mode, the air in the space cannot be discharged, and therefore the first heat insulation layer 13 is filled with air. It can be understood that the cold water in the second chamber 21b is isolated from the disk body 11 by the first heat insulating layer 13, and the air is a poor heat conductor, and the heat of the normal-temperature water above the disk body 11 is not transferred to the cold water layer below through the disk body 11, so that the normal-temperature water in the first chamber 21a is prevented from heat exchange with the cold water in the second chamber 21b, thereby preventing the temperature of the warm water in the first chamber 21a from being lowered.

Wherein, the distance that the ring muscle 15 protrudes in dish body 11 one side should not be too big to when guaranteeing that diverter plate 10 has better heat-proof effect, leave sufficient water storage space for second cavity 21b (under the prerequisite that does not increase cold jar 21 volume), in this application embodiment, the distance that ring muscle 15 protrudes in dish body 11 one side is 15-25 mm.

It will be appreciated that the annular rib 15 is provided adjacent the outer periphery of the disc body 11 to further reduce contact of the disc body 11 with cold water and to provide optimum thermal insulation of the diverter disc 10. Wherein, the ring rib 15 is arranged near the outer peripheral edge of the disk body 11, rather than being formed at the outer peripheral edge of the disk body 11, that is, a certain distance exists between the outer peripheral wall of the ring rib 15 and the outer peripheral wall of the disk body 11, as shown in fig. 2, so that the overall strength of the disk body 11 can be enhanced, and the disk body 11 is prevented from deforming after injection molding.

Referring to fig. 1 and 2, in an embodiment of the present application, an insulating pipe 16 is connected to a side of the tray body 11 facing the first water outlet pipe 12, and the insulating pipe 16 is sleeved on an outer periphery of the first water outlet pipe 12 and forms the second insulating layer 14 at an interval with the first water outlet pipe 12.

The heat insulation pipe 16 and the tray body 11 may be connected separately, for example, the heat insulation pipe 16 and the tray body 11 may be connected by screw, inserted, or welded by heat fusion; the heat insulating pipe 16 and the tray body 11 may be integrally formed. In the embodiment of the present application, in order to facilitate production and improve production efficiency, the heat insulating pipe 16 and the tray body 11 are formed by integral injection molding.

As can be appreciated, since the heat insulation pipe 16 and the tray body 11 are integrally formed by injection molding, the wall thickness of the heat insulation pipe 16 is gradually decreased from the end connected with the tray body 11 to the end away from the tray body 11 for facilitating the mold release.

Specifically, when the water level rises until the water level comes into contact with the bottom of the heat insulating pipe 16 while the normal-temperature water in the first chamber 21a flows into the second chamber 21b, the air around the heat insulating pipe 16 is pushed by the water and discharged, and at this time, the water seals the space formed by the heat insulating pipe 16 and the first water outlet pipe 12 at an interval, that is, the water seals the second heat insulating layer 14, and the air inside cannot be discharged, so that the second heat insulating layer 14 is filled with air. In this way, the first water outlet pipe 12 is isolated from the cold water in the second chamber 21b, so that the warm water in the first water outlet pipe 12 is prevented from exchanging heat with the cold water in the second chamber 21b, and the temperature in the first water outlet pipe 12 is prevented from being reduced.

It will be appreciated that the length of the insulated pipe 16 is less than the length of the first outlet pipe 12 in order to prevent the insulated pipe 16 from interfering with the wall of the cold tank 21 and interfering with the connection of the first outlet pipe 12 to the bottom wall of the cold tank 21. Of course, the length of the insulated pipe 16 is not too short, and in the embodiment of the present invention, the length of the insulated pipe 16 is different by 2-4mm compared to the length of the first water outlet pipe 12, so that the second insulating layer 14 has a sufficient depth to ensure that the first water outlet pipe 12 is isolated from the cold water in the second chamber 21b, thereby producing the best insulating effect.

Because people's improvement to drinking water quality requirement, the water dispenser still is equipped with ultraviolet lamp 50 in order to disinfect to water, please refer to fig. 1 and fig. 2, in this application another embodiment, the dish body 11 is equipped with the sleeve pipe 17 that supplies ultraviolet lamp 50 to insert in the protruding one side of first outlet pipe 12 that faces, and the dish body 11 is equipped with the opening of sleeve pipe 17 intercommunication, sleeve pipe 17 is located in first insulating layer 13. By providing the sleeve 17, the influence of the uv lamp 50 on the first insulating layer 13 can be avoided.

Further, in another embodiment of the present invention, the diverter tray 10 further includes a sealing plate connected to an end of the ring rib 15 away from the tray body 11 to seal the first insulating layer 13. The first thermal insulation layer 13 is filled with thermal insulation members (materials with low thermal conductivity), or the first thermal insulation layer 13 is vacuumized. The first sealing plate and the ring rib 15 can be connected by screw thread, inserted (interference fit), or welded by heat fusion.

Similarly, in other embodiments, the diverter tray 10 may further include a second cover plate attached to the end of the insulating tube 16 remote from the tray body 11 to seal the second insulating layer 14. Wherein, the second insulating layer 14 is filled with heat insulation members, or the second insulating layer 14 is vacuumized.

The above detailed descriptions of the diverter tray, the cold tank assembly and the water dispenser provided in the embodiments of the present application, and the specific examples are applied herein to explain the principle and the embodiments of the present application, and the descriptions of the above embodiments are only used to help understand the method and the core ideas of the present application; meanwhile, for those skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims

1. A diverter plate for mounting to a cold tank of a water dispenser, the diverter plate comprising:

the disc body is arranged in the cold tank and divides an inner cavity of the cold tank into a first cavity and a second cavity which are arranged at intervals; and

2. The diverter tray according to claim 1, wherein a ring rib is protruded from a side of the tray body facing the first outlet pipe, the ring rib is disposed around the first outlet pipe, and the ring rib and the tray body enclose to form the first thermal insulation layer.

3. The diverter tray according to claim 2, wherein the ring rib is disposed proximate an outer peripheral edge of the tray body.

4. The diverter tray according to claim 1, wherein the first insulation layer is filled with insulation or air.

5. The diverter tray according to any one of claims 1 to 4, wherein a heat insulation pipe is connected to one side of the tray body facing the first water outlet pipe, and the heat insulation pipe is sleeved on the periphery of the first water outlet pipe and spaced from the first water outlet pipe to form the second heat insulation layer.

6. The diverter tray according to claim 5, wherein the wall thickness of the insulating tube decreases from the end connected to the tray body to the end remote from the tray body.

7. The diverter tray according to claim 1, wherein the second insulation layer is filled with insulation or air.

8. The diverter tray according to claim 1, wherein a sleeve for insertion of a uv lamp is protruded from a side of the tray body facing the first outlet pipe, and the tray body is provided with an opening communicating with the sleeve, the sleeve being located in the first insulating layer.

9. The diverter tray according to claim 2 further comprising a first sealing plate attached to an end of said ring rib remote from said tray body to seal said first insulating layer.

10. The diverter tray according to claim 9, wherein the first insulation layer is filled with insulation; or the first heat insulation layer is arranged in a vacuum pumping mode.

11. A cold-can assembly comprising a cold can and a diverter tray as claimed in any one of claims 1 to 10 mounted in the cold can.

12. A cold-tank assembly according to claim 11, further comprising cooling means mounted to the peripheral wall of said second chamber for absorbing heat from the water in said second chamber.

13. A cold-tank assembly according to claim 11, wherein the bottom wall of the cold tank is provided with a second outlet pipe communicating with the second chamber, and the end of the first outlet pipe remote from the tray body is connected to the second outlet pipe.

14. A water dispenser comprising a cold can assembly as claimed in any one of claims 11 to 12.

15. The water dispenser of claim 14 further comprising a hot can;