CN215473004U - Refrigerator door seals magnetic stripe shaping cooling device - Google Patents

Abstract

The utility model discloses a refrigerator door seal magnetic stripe forming and cooling device, which relates to the technical field of extrusion molding and cooling devices and comprises the following components: the cooling device comprises a cooler, a condensation mechanism and an auxiliary cooling mechanism, wherein a cooling groove is formed in the top of the cooler, a condensation cavity is formed in the cooler, an auxiliary cooling cavity is formed in the cooler, and the condensation mechanism is arranged in the condensation cavity. According to the door seal magnetic stripe cooling device, the refrigerant in the storage tank is compressed into liquid through the compressor, so that the heat in the refrigerant is released, the heat released by the refrigerant is removed through the condenser, the liquefied refrigerant is conveyed into the condenser pipe through the output pipe, and the cooling water in the cooling tank is cooled through the condenser pipe, so that the technical problem that the cooling efficiency of the door seal magnetic stripe is low due to the fact that the temperature of the circulating water rises after the magnetic stripe is cooled for a long time in the conventional cooling device and the door seal magnetic stripe can be cooled again after the circulating water is cooled is solved.

Description

Refrigerator door seals magnetic stripe shaping cooling device

Technical Field

The utility model relates to the technical field of extrusion molding cooling devices, in particular to a refrigerator door seal magnetic stripe molding cooling device.

Background

The refrigerator door seal is a refrigerator accessory used between a refrigerator door body and a refrigerator body for sealing, and consists of two parts, wherein one part is a soft polyvinyl chloride (SPVC) outer sleeve, and the other part is a magnetic adhesive tape;

the prior patent (publication number: CN210061967U) discloses a refrigerator door seal magnetic stripe forming and cooling device, wherein a magnetic stripe runs smoothly in a box body, the cooling time is sufficient, cooling water can circulate automatically, scale is removed at the same time, the magnetic stripe cooling effect is good, the magnetic stripe production efficiency can be improved while the magnetic stripe quality is ensured, and the device is suitable for being popularized and used when the refrigerator door seal magnetic stripe is produced and manufactured;

however, the above-mentioned refrigerator door seals the magnetic stripe shaping cooling device and still has the following problem in the actual use: because foretell refrigerator door seals magnetic stripe shaping cooling device only seals the magnetic stripe cooling through the circulating water to extrusion molding's door, then can lead to after long-time magnetic stripe cooling, the temperature of circulating water can rise, makes the circulating water can't cool down the magnetic stripe again, just can cool down the door again after need waiting for the circulating water cooling, leads to sealing the cooling efficiency of magnetic stripe lower to the door.

SUMMERY OF THE UTILITY MODEL

The utility model provides a refrigerator door seal magnetic stripe forming and cooling device, which solves the technical problem that in the existing cooling device, after a magnetic stripe is cooled for a long time, the temperature of circulating water is increased, and the door seal magnetic stripe can be cooled again after the cooling of the circulating water is needed, so that the cooling efficiency of the door seal magnetic stripe is low.

In order to solve the technical problem, the utility model provides a refrigerator door seal magnetic stripe forming and cooling device, which comprises: the cooling device comprises a cooler, a condensing mechanism and an auxiliary cooling mechanism, wherein the top of the cooler is provided with a cooling groove, a condensing cavity is formed in the cooler, an auxiliary cooling cavity is formed in the cooler, the condensing mechanism is arranged in the condensing cavity, and the auxiliary cooling mechanism is arranged in the auxiliary cooling cavity;

condensation mechanism includes the storage jar, storage jar fixed mounting is in the condensation intracavity, condensation intracavity fixed mounting has the compressor, condensation intracavity fixed mounting has the condenser, just all communicate through the connecting pipe between compressor and the storage jar and the condenser, one side fixedly connected with output tube of condenser, the one end of output tube is located the interior bottom of cooling bath, the interior bottom fixed mounting of cooling bath has the condenser pipe, the one end and the output tube fixed connection of condenser pipe.

Preferably, supplementary cooling body includes the cooling tube, cooling tube fixed mounting is in the interior bottom of supplementary cooling chamber, just cooling tube and condenser pipe fixed connection, the other end and the storage jar fixed connection of cooling tube cool down the cooling water of supplementary cooling intracavity through the cooling tube to in discharging the cooling water of supplementary cooling intracavity into the cooling bath, the hotter cooling water of replacement part.

Preferably, a water inlet and a water outlet are respectively formed in the inner side wall of the auxiliary cooling cavity, a mounting cavity is formed in the cooler, a positive air pump is fixedly mounted in the mounting cavity, an exhaust hole is formed in the top of the inner side wall of the mounting cavity, the positive air pump runs, the input end of the positive air pump is connected in the exhaust hole in an inserting mode, air in the auxiliary cooling cavity can be discharged by the positive air pump, the auxiliary cooling cavity is in a negative pressure state, cooling liquid in the cooling groove is sucked into the auxiliary cooling cavity through the water inlet, and the cooling liquid in the auxiliary cooling cavity can be discharged into the cooling groove through the water outlet along with continuous running of the positive air pump.

Preferably, a splicing hole is formed in one side of the condenser, a heat dissipation motor is fixedly mounted on one side of the condenser, the rotating end of the heat dissipation motor is spliced in the splicing hole, a plurality of heat dissipation fan blades are fixedly mounted on the outer side of the rotating end of the heat dissipation motor at equal intervals, the heat dissipation fan blades are driven by the heat dissipation motor to rotate, the condenser can be cooled, and the amount of heat released by liquid coolant in the condenser is discharged.

Preferably, the mounting opening is opened to the inside wall in condensation chamber, fixed mounting has the guide plate in the mounting opening, and heat accessible mounting opening discharges to the direction through the guide plate can prevent by the exhaust steam rise.

Preferably, a plurality of air inlets are formed in the inner top of the condensation cavity at equal intervals, and the air inlets are formed, so that external cold air can flow into the condensation cavity through the air inlets and cool the compressor and the condenser.

Preferably, a plurality of air outlets are formed in the top of the mounting cavity at equal intervals, and air in the auxiliary cooling cavity is sucked by the positive air pump and then can be discharged through the air outlets.

Preferably, a dust filter net is fixedly arranged in the air outlet and can filter dust in the air.

Compared with the prior art, the refrigerator door seal magnetic stripe forming and cooling device provided by the utility model has the following beneficial effects:

1. according to the utility model, the refrigerant in the storage tank is compressed into liquid through the compressor, so that the heat in the refrigerant is released, the heat released by the refrigerant is removed through the condenser, the liquefied refrigerant is conveyed into the condenser pipe through the output pipe, the cooling water in the cooling tank is cooled through the condenser pipe, and the cooling water in the cooling tank can continuously cool the door sealing magnetic strip through a cooling water cooling mode in the cooling tank.

2. According to the utility model, air in the auxiliary cooling cavity is discharged through the positive air pump, the cooling liquid in the cooling tank is sucked into the auxiliary cooling cavity through the water inlet, the cooling liquid in the auxiliary cooling cavity is cooled through the cooling pipe arranged at the bottom of the auxiliary cooling cavity, and the cooled cooling liquid is discharged into the cooling tank through the water outlet.

Drawings

FIG. 1 is a schematic structural diagram of a refrigerator door seal magnetic stripe forming and cooling device;

FIG. 2 is a sectional top view of a magnetic stripe forming and cooling device for a refrigerator door seal;

FIG. 3 is a front cross-sectional view of a refrigerator door seal magnetic stripe forming and cooling device;

fig. 4 is an enlarged view of a portion a in fig. 2.

Reference numbers in the figures: 1. a cooler; 2. a cooling tank; 3. a condensation chamber; 4. storing the tank; 5. a compressor; 6. a condenser; 7. an output pipe; 8. a condenser tube; 9. an auxiliary cooling chamber; 10. a cooling tube; 11. a water inlet; 12. a water outlet; 13. a mounting cavity; 14. a positive air pump; 15. an exhaust hole; 16. inserting holes; 17. a heat dissipation motor; 18. a heat dissipation fan blade; 19. an exhaust hole; 20. a baffle; 21. an air inlet; 22. and an air outlet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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 invention.

In a first embodiment, as shown in fig. 1 to 4, a cooling apparatus for forming a magnetic stripe of a refrigerator door seal comprises: the device comprises a cooler 1, a condensing mechanism and an auxiliary cooling mechanism, wherein the top of the cooler 1 is provided with a cooling groove 2, a condensing cavity 3 is formed in the cooler 1, an auxiliary cooling cavity 9 is formed in the cooler 1, the condensing mechanism is arranged in the condensing cavity 3, and the auxiliary cooling mechanism is arranged in the auxiliary cooling cavity 9;

the condensing mechanism comprises a storage tank 4, the storage tank 4 is fixedly arranged in the condensing cavity 3, a compressor 5 is fixedly arranged in the condensing cavity 3, a condenser 6 is fixedly arranged in the condensing cavity 3, and the compressor 5 is communicated with the storage tank 4 and the condenser 6 through connecting pipes, one side of the condenser 6 is fixedly connected with an output pipe 7, one end of the output pipe 7 is positioned at the inner bottom of the cooling tank 2, a condenser pipe 8 is fixedly arranged at the inner bottom of the cooling tank 2, one end of the condenser pipe 8 is fixedly connected with the output pipe 7, the coolant in the storage tank 4 is sucked in by the compressor 5, and the coolant in the gaseous state is compressed into the coolant in the liquid state, which flows into the condenser 6 through the communicating pipe, and the liquid coolant after being cooled is conveyed into a condensation pipe 8 through an output pipe 7, and the cooling liquid in the cooling tank 2 is subjected to heat exchange and cooling.

In the second embodiment, on the basis of the first embodiment, the auxiliary cooling mechanism includes the cooling pipe 10, the cooling pipe 10 is fixedly installed at the inner bottom of the auxiliary cooling cavity 9, the cooling pipe 10 is fixedly connected with the condensation pipe 8, the other end of the cooling pipe 10 is fixedly connected with the storage tank 4, the coolant after heat exchange is conveyed into the cooling pipe 10 through the condensation pipe 8, and the cooling liquid in the auxiliary cooling cavity 9 is cooled.

Third embodiment, on the basis of first embodiment, a water inlet 11 and a water outlet 12 have been respectively seted up to the inside wall of auxiliary cooling chamber 9, installation cavity 13 has been seted up in cooler 1, fixed mounting has just empty pump 14 in installation cavity 13, exhaust hole 15 has been seted up at the top of the inside wall of installation cavity 13, just empty pump 14 operates, and discharge the air in auxiliary cooling chamber 9 through exhaust hole 15, make the interior of auxiliary cooling chamber 9 be the negative pressure state, the internal gas pressure of auxiliary cooling chamber 9 is lower, can inhale the coolant liquid in cooling bath 2 through water inlet 11, along with the operation of just empty pump 14, the internal pressure of auxiliary cooling chamber 9 does not rise, the coolant liquid in cooling bath 2 can constantly be inhaled through water inlet 11 by auxiliary cooling chamber 9, the coolant liquid in auxiliary cooling chamber 9 can discharge into cooling bath 2 again.

In this embodiment: the positive air pump 14 uses VRD-4.

Fourth embodiment, on the basis of first embodiment, spliced eye 16 has been seted up to one side of condenser 6, one side fixed mounting of condenser 6 has heat dissipation motor 17, and the rotation end of heat dissipation motor 17 is pegged graft in spliced eye 16, the equidistant fixed mounting in the outside of heat dissipation motor 17 rotation end has a plurality of heat dissipation flabellums 18, drive heat dissipation flabellum 18 through heat dissipation motor 17 and rotate, make heat dissipation flabellum 18 can disturb the interior air current of condensation chamber 3, and cool down condenser 6, can promote the radiating efficiency of condenser 6.

In this embodiment: YC7134 is adopted as the plug hole 16.

Fifth embodiment, on the basis of the first embodiment, the inner side wall of the condensation chamber 3 is provided with a mounting hole 19, a flow guide plate 20 is fixedly mounted in the mounting hole 19, and through the mounting hole 19, hot gas in the condensation chamber 3 can be discharged through the cooling pipe 10, and the discharged hot gas is guided by the flow guide plate 20.

Sixth embodiment, on the basis of the first embodiment, a plurality of air inlets 21 are formed at equal intervals on the inner top of the condensation chamber 3, and through the formation of the air inlets 21, the external cold air can enter the condensation chamber 3 through the air inlets 21, so as to replace the hot air in the condensation chamber 3.

In the seventh embodiment, on the basis of the third embodiment, a plurality of air outlets 22 are formed at equal intervals on the top of the mounting cavity 13, and the air in the auxiliary cooling cavity 9 can be sucked by the positive air pump 14 and then discharged through the air outlets 22 by the opening of the air outlets 22.

In the eighth embodiment, on the basis of the seventh embodiment, a dust filter is fixedly arranged in the air outlet 22, so that dust in the air can be filtered, and the use of the air outlet 22 is facilitated.

The working principle is as follows:

when the door seal magnetic stripe needs to be cooled, the condensing mechanism is started;

the condensation mechanism comprises the following implementation steps:

the first step is as follows: the compressor 5 sucks in the coolant in the storage tank 4 and pressurizes the coolant to condense the coolant from the gas;

the second step is that: the condensed liquid coolant is conveyed into the condenser 6 through a communicating pipe, and heat released when the liquid coolant is condensed is dissipated through the condenser 6;

the third step: the cooled coolant is conveyed into the condenser pipe 8 through the output pipe 7, and the heat exchange and cooling are carried out on the coolant in the cooling tank 2 through the condenser pipe 8.

When the cooling liquid in the cooling tank 2 is subjected to heat exchange and cooling, the auxiliary cooling mechanism is synchronously started;

the auxiliary cooling mechanism comprises the following implementation steps:

the first step is as follows: the positive air pump 14 starts to operate, and the input end of the positive air pump 14 exhausts the air in the auxiliary cooling cavity 9 through the exhaust hole 15, so that the auxiliary cooling cavity 9 is in a negative pressure state;

the second step is that: the auxiliary cooling cavity 9 sucks cooling liquid in the cooling tank 2 through the water inlet 11, and performs heat exchange and temperature reduction on the cooling liquid sucked in the auxiliary cooling cavity 9 through the cooling pipe 10;

the third step: the coolant liquid through the heat transfer in the auxiliary cooling chamber 9 is discharged into the cooling tank 2 through the water outlet 12, and the coolant liquid which is cooling the door seal magnetic stripe in the cooling tank 2 is subjected to heat transfer and cooling, so that the heat exchange efficiency is improved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a refrigerator door seals magnetic stripe shaping cooling device which characterized in that includes: the device comprises a cooler (1), a condensing mechanism and an auxiliary cooling mechanism, wherein a cooling groove (2) is formed in the top of the cooler (1), a condensing cavity (3) is formed in the cooler (1), an auxiliary cooling cavity (9) is formed in the cooler (1), the condensing mechanism is arranged in the condensing cavity (3), and the auxiliary cooling mechanism is arranged in the auxiliary cooling cavity (9);

condensation mechanism includes storage jar (4), storage jar (4) fixed mounting is in condensation chamber (3), fixed mounting has compressor (5) in condensation chamber (3), fixed mounting has condenser (6) in condensation chamber (3), just all communicates through the connecting pipe between compressor (5) and storage jar (4) and condenser (6), one side fixedly connected with output tube (7) of condenser (6), the one end of output tube (7) is located the interior bottom of cooling bath (2), the interior bottom fixed mounting of cooling bath (2) has condenser pipe (8), the one end and output tube (7) fixed connection of condenser pipe (8).

2. The refrigerator door seal magnetic stripe forming cooling device according to claim 1, wherein the auxiliary cooling mechanism comprises a cooling pipe (10), the cooling pipe (10) is fixedly installed at the inner bottom of the auxiliary cooling cavity (9), the cooling pipe (10) is fixedly connected with the condensation pipe (8), and the other end of the cooling pipe (10) is fixedly connected with the storage tank (4).

3. The refrigerator door seal magnetic stripe forming cooling device according to claim 1, characterized in that the inside wall of the auxiliary cooling cavity (9) is respectively provided with a water inlet (11) and a water outlet (12), the cooler (1) is internally provided with an installation cavity (13), the installation cavity (13) is internally and fixedly provided with a positive air pump (14), and the top of the inside wall of the installation cavity (13) is provided with an exhaust hole (15).

4. The refrigerator door seal magnetic stripe forming and cooling device as claimed in claim 1, wherein a plugging hole (16) is formed in one side of the condenser (6), a heat dissipation motor (17) is fixedly installed on one side of the condenser (6), the rotating end of the heat dissipation motor (17) is plugged in the plugging hole (16), and a plurality of heat dissipation fan blades (18) are fixedly installed on the outer side of the rotating end of the heat dissipation motor (17) at equal intervals.

5. The forming and cooling device for the magnetic strip of the refrigerator door seal according to claim 1, wherein a mounting opening (19) is formed in the inner side wall of the condensation chamber (3), and a guide plate (20) is fixedly mounted in the mounting opening (19).

6. The forming and cooling device for the magnetic strip of the refrigerator door seal according to claim 1, wherein a plurality of air inlets (21) are formed at the inner top of the condensation chamber (3) at equal intervals.

7. The forming and cooling device for the magnetic strip of the refrigerator door seal according to claim 3, wherein a plurality of air outlets (22) are formed at the top of the mounting cavity (13) at equal intervals.

8. The forming and cooling device for the magnetic strip of the refrigerator door seal according to claim 7, wherein a dust filter screen is fixedly arranged in the air outlet (22).

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