CN204520248U - For cooking apparatus refrigerating plant and there is its juice extractor, kettle - Google Patents

Abstract

The utility model discloses a kind of refrigerating plant for cooking apparatus and there is its juice extractor, kettle, described cooking apparatus comprises juice extractor or kettle, described refrigerating plant comprises: semiconductor chilling plate, and the cold junction of described semiconductor chilling plate is suitable for being connected with the kettle body of the squeezing cup of described juice extractor or described kettle; Radiator, described radiator is connected with the hot junction of described semiconductor chilling plate.According to the refrigerating plant for cooking apparatus of the present utility model, can realize freezing quickly and safely, easy to use.

Description

For cooking apparatus refrigerating plant and there is its juice extractor, kettle

Technical field

The utility model belongs to household appliance technical field, in particular to a kind of refrigerating plant for cooking apparatus and juice extractor and the kettle with this refrigerating plant.

Background technology

Existing a lot of cooking apparatus is not with refrigerating plant mostly, if need cooling after having cooked, needs cooked food or drink to put into refrigerator.

Such as juice extractor, the current juice extractor juice temperature come of squeezing out is all the original temperature of fruit, even higher in the temperature that the temperature of the fruit juice of squeezing the juice out is more original than fruit, in hot summer, in order to strengthen the mouthfeel of fruit juice, the fruit juice of squeezing the juice out is needed to put into airtight container, put refrigerator freezing into again, freezing required time is relevant with the temperature of refrigerator, if be placed on refrigerating chamber, the temperature of fruit juice declines 7 DEG C of-8 DEG C of need several hours, if be placed on refrigerating chamber, the temperature of fruit juice declines 7 DEG C of-8 DEG C of need at least half an hour.The method long complicated operation consuming time of this frozen juice, and need to support the use refrigerator.More seriously, a lot of fruit juice is oxidizable, such as cider, places that just to start oxidation more than 10 minutes serious, and the freshness of fruit juice, form and aspect and mouthfeel etc. are obviously deteriorated, and there is room for improvement

For kettle, the boiled rear temperature of water is very high, and in hot summer, if wish to drink frozen water, need first to wait boiling water to be cooled to just can put into refrigerator freezing close to normal temperature, the required time is longer, there is room for improvement.

Utility model content

The utility model is intended to solve one of technical problem in correlation technique at least to a certain extent.For this reason, an object of the present utility model is to propose the fast refrigerating plant for cooking apparatus of a kind of cooling velocity.

Another object of the present utility model is to propose a kind of juice extractor with above-mentioned refrigerating plant.

Another object of the present utility model is to propose a kind of kettle with above-mentioned refrigerating plant.

According to the refrigerating plant for cooking apparatus of the utility model first aspect embodiment, described cooking apparatus comprises juice extractor or kettle, described refrigerating plant comprises: semiconductor chilling plate, and the cold junction of described semiconductor chilling plate is suitable for being connected with the kettle body of the squeezing cup of described juice extractor or described kettle; Radiator, described radiator is connected with the hot junction of described semiconductor chilling plate.

According to the refrigerating plant for cooking apparatus of the utility model first aspect embodiment, can realize freezing quickly and safely, easy to use.

In addition, following additional technical characteristic can also be had according to the refrigerating plant for cooking apparatus of the utility model above-described embodiment:

Alternatively, described radiator comprises: cooling base, and the one side of described cooling base is fitted with described hot junction; Radiating fin, described radiating fin is connected with the another side of described cooling base.

Further, described radiator is alumiaum article or copper fitting.

Alternatively, the described refrigerating plant for cooking apparatus, also comprises: blower fan, and described blower fan is suitable for described radiator heat-dissipation.

Alternatively, the described refrigerating plant for cooking apparatus, also comprises: cooler, and the one side of described cooler is suitable for being connected with described squeezing cup or described kettle body and another side is connected with described cold junction.

Further, thermal conductive silicon lipid layer is all folded with between described radiator and described semiconductor chilling plate and between described cooler and described semiconductor chilling plate.

Alternatively, described cooler is suitable for the squeezing cup of coated described juice extractor or the kettle body of described kettle, and the outer bottom of described cold junction and described cooler is fitted.

Alternatively, described cooler comprises: cold scattering pedestal and cold scattering fin, described cold scattering fin is connected with the one side of described cold scattering pedestal, and described cold scattering fin is suitable for stretching in the spatial accommodation of described squeezing cup or described kettle body, another side and the described cold junction of described cold scattering pedestal are fitted, and described cold scattering pedestal is suitable for forming at the bottom of at least part of glass of described squeezing cup or at least part of diapire of described kettle body.

Preferably, described semiconductor chilling plate is arranged with the guard circle identical with its thickness.

According to the juice extractor of the utility model second aspect embodiment, comprise the refrigerating plant for cooking apparatus of first aspect embodiment.

Further, described juice extractor also comprises: spiral propeller, and described spiral propeller is connected with the motor shaft of described juice extractor to be suitable for driving the liquid flow in described squeezing cup.

According to the kettle of the utility model third aspect embodiment, comprise the refrigerating plant for cooking apparatus of first aspect embodiment.

Identical with the refrigerating plant for cooking apparatus of first aspect embodiment with the advantage of the kettle of third aspect embodiment according to the juice extractor of the utility model second aspect embodiment, do not repeat them here.

Accompanying drawing explanation

Fig. 1 is the structural representation of the refrigerating plant according to a kind of embodiment of the utility model;

Fig. 2 is the structural representation (squeezing cup is shown) of the refrigerating plant according to the another kind of embodiment of the utility model;

Fig. 3 is the structural representation (not shown squeezing cup) of the refrigerating plant according to the another kind of embodiment of the utility model;

Fig. 4 is the structural representation of the refrigerating plant according to another embodiment of the utility model;

Fig. 5 is the structural representation of the juice extractor according to the utility model embodiment;

Fig. 6 is the enlarged drawing at B place in Fig. 5;

Fig. 7 is the structural representation of the cooking apparatus according to the utility model embodiment.

Reference numeral:

Juice extractor 1000,

Refrigerating plant 100,

Radiating module 10,

Cooler 1, cold scattering pedestal 11, cold scattering fin 12,

Semiconductor chilling plate 2, cold junction 21, hot junction 22,

Radiator 3, cooling base 31, radiating fin 32,

Heat pipe 41, fin 42,

Water-cooled assembly 5, cooling water tank 51, water pump 52, radiating tube 53, cooling bath 54, pipeline 55,

Blower fan 6,

Squeezing cup 200, spiral propeller 300, temperature-detecting device 400, motor shaft 500, controller 600, shell 710, power panel 720, net-filter assembly 730, motor 740, stick pusher 750, residue receiving cup 760.

Detailed description of the invention

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Be exemplary below by the embodiment be described with reference to the drawings, be intended to for explaining the utility model, and can not be interpreted as restriction of the present utility model.

In description of the present utility model, it will be appreciated that, term " thickness ", " on ", D score, " end ", " interior ", " outward ", etc. instruction orientation or position relationship be based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of the device of instruction or hint indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.

In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise at least one this feature.In description of the present utility model, the implication of " multiple " is at least two, such as two, three etc., unless otherwise expressly limited specifically.

In the utility model, unless otherwise clearly defined and limited, the term such as term " installation ", " being connected ", " connection ", " fixing " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or integral; Can be mechanical connection, can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals or the interaction relationship of two elements, unless otherwise clear and definite restriction.For the ordinary skill in the art, the concrete meaning of above-mentioned term in the utility model can be understood as the case may be.

In the utility model, unless otherwise clearly defined and limited, fisrt feature second feature " on " or D score can be that the first and second features directly contact, or the first and second features are by intermediary mediate contact.And, fisrt feature second feature " on ", " top " and " above " but fisrt feature directly over second feature or oblique upper, or only represent that fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " below " and " below " can be fisrt feature immediately below second feature or tiltedly below, or only represent that fisrt feature level height is less than second feature.

Below with reference to the accompanying drawings and describe the utility model in detail in conjunction with the embodiments.

The cooking apparatus according to the utility model embodiment is described in detail referring to Fig. 1-Fig. 7.Cooking apparatus comprises cup and refrigerating plant 100.Cooking apparatus can be juice extractor 1000, or cooking apparatus can be kettle, and refrigerating plant 100 is mainly used in cooling the liquid in juice extractor 1000 or the liquid in kettle fast.Cup can be the squeezing cup 200 of juice extractor 1000 or the kettle body of kettle, and squeezing cup 200 prepares to the fruit juice of user for accessing.

Refrigerating plant 100 comprises semiconductor chilling plate 2 and radiating module 10, and in order to improving radiating effect, cooking apparatus can also comprise blower fan 6, and blower fan 6 dispels the heat for giving radiating module 10.

Semiconductor chilling plate 2 mainly utilizes the Peltier effect of semi-conducting material to realize refrigeration, when the galvanic couple that direct current is connected into by two kinds of different semi-conducting materials, can absorb heat respectively and release heat, and maintain certain temperature difference at the two ends of galvanic couple.Semiconductor chilling plate 2 comprises hot junction 22 and cold junction 21, can maintain certain temperature difference between hot junction 22 and cold junction 21.

The cold junction 21 of semiconductor chilling plate 2 is connected with cup, to reduce rapidly the temperature of liquid in kettle body, radiating module 10 is connected with the hot junction 22 of semiconductor chilling plate 2, to absorb the heat in the hot junction 22 of semiconductor chilling plate 2, reduces the temperature in the hot junction 22 of semiconductor chilling plate 2.

Like this, the cold junction 21 of semiconductor chilling plate 2 from the liquid continuous absorption heat in cup, can reduce the temperature of the liquid in cup fast.

The refrigerating plant 100 for cooking apparatus according to some embodiments of the utility model is described in detail referring to Fig. 1-Fig. 7.

In first preferred embodiment of the present utility model, as shown in Figure 1, the refrigerating plant 100 for cooking apparatus comprises semiconductor chilling plate 2 and radiating module 10, and radiating module 10 comprises radiator 3.

The cold junction 21 of semiconductor chilling plate 2 is suitable for being connected with the squeezing cup 200 of juice extractor 1000, and to reduce rapidly the temperature of liquid in squeezing cup 200, or the cold junction 21 of semiconductor chilling plate 2 is suitable for being connected with the kettle body of kettle, to reduce rapidly the temperature of liquid in kettle body; The hot junction 22 of semiconductor chilling plate 2 is connected with radiator 3, to absorb the heat in the hot junction 22 of semiconductor chilling plate 2, reduces the temperature in the hot junction 22 of semiconductor chilling plate 2.Like this, the cold junction 21 of semiconductor chilling plate 2 can from the liquid continuous absorption heat in the liquid in squeezing cup 200 or kettle body, the temperature of liquid in quick reduction squeezing cup 200 or in kettle body, such as the temperature of squeezing cup 200 is reduced to 0-15 degree, this temperature can according to user need select.

The volume of the liquid of the cooling time of refrigerating plant 100 and refrigeration work consumption, needs refrigeration and need the temperature number form reduced to have functional relation: time=specific heat capacity × liquid volume (liter) × fluid density × cooling number of degrees ÷ refrigeration work consumption.Such as when refrigeration work consumption is 100W, lower the temperature 8 DEG C to the fruit juice of 500ml, required time was less than 3 minutes.

Further, as shown in Figure 1, the radiating efficiency of radiator 3 is high and structure simple, can accelerate the heat loss speed in the hot junction 22 of semiconductor chilling plate 2, and then can cool the liquid in squeezing cup 200 or kettle body quickly.

As shown in Figure 1, radiator 3 can comprise cooling base 31 and radiating fin 32, and the one side of cooling base 31 is fitted with hot junction 22, and radiating fin 32 is connected with the another side of cooling base 31.The structure of radiator 3 is simple, is conducive to the size reducing whole refrigerating plant 100.It should be noted that, in the following description, for convenience of description, the upper surface of parts is referred to as one side by spy, and the lower surface of parts is referred to as another side.

The cooling base 31 of radiator 3 is larger with the contact area in the hot junction 22 of semiconductor chilling plate 2, therebetween rate of heat exchange is faster, in order to reduce contact gap between cooling base 31 bonded to each other and hot junction 22 to the impact of radiating efficiency, further, thermal conductive silicon lipid layer can be folded with between radiator 3 and semiconductor chilling plate 2, that is, thermal conductive silicon lipid layer can be folded with between the cooling base 31 of radiator 3 and the hot junction 22 of semiconductor chilling plate 2, high and the contact gap can filled between the cooling base 31 of radiator 3 and the hot junction 22 of semiconductor chilling plate 2 of the thermal conductivity of thermal conductive silicon lipid layer.Thus, improve the rate of heat exchange between radiator 3 and semiconductor chilling plate 2, and then the refrigerating speed of refrigerating plant 100 is promoted.

Alternatively, radiator 3 can be alumiaum article, and the thermal conductivity of aluminium is good, and quality is light, and low price, be conducive to the weight alleviating refrigerating plant 100, reduce manufacturing cost.

Alternatively, radiator 3 can be also copper fitting, and the thermal conductivity of copper is high, promptly can carry out heat exchange with the hot junction 22 of semiconductor chilling plate 2, and then optimizes the refrigeration of refrigerating plant 100.

Further, as shown in Figure 1, cooking apparatus can also comprise blower fan 6, and blower fan 6 is suitable for dispelling the heat to radiator 3, to accelerate the heat loss of radiator 3.In order to optimize the radiating effect of radiator 3 further, as shown in Figure 1, the wind direction (as shown in the arrow A in Fig. 1) that blower fan 6 blows out can face the radiating fin 32 of radiator 3.

The cold junction 21 of semiconductor chilling plate 2 is suitable for cooling the liquid in squeezing cup 200 or kettle body.Further, the refrigerating plant 100 for cooking apparatus can also comprise cooler 1, and the one side of cooler 1 is suitable for and cup, and such as squeezing cup 200 or kettle body are connected, and the another side of cooler 1 is connected with the cold junction 21 of semiconductor chilling plate 2.That is, the cold junction 21 of semiconductor chilling plate 2 is connected with squeezing cup 200 or kettle body by cooler 1, the cold junction 21 of the semiconductor chilling plate 2 that on the one hand temperature can be prevented too low damages squeezing cup 200 or kettle body, can optimize the heat exchanger effectiveness of semiconductor chilling plate 2 and liquid in squeezing cup 200 or kettle body on the other hand.

Cooler 1 can be alumiaum article, and the thermal conductivity of aluminium is good, and quality is light, and low price, be conducive to the weight alleviating refrigerating plant 100, reduce manufacturing cost.

Alternatively, cooler 1 can be copper fitting, and the thermal conductivity of copper and ductility are all good, according to the shape being made as needs better, promptly can carry out heat exchange with the cold junction 21 of semiconductor chilling plate 2, and then accelerates the refrigerating speed of refrigerating plant 100.

Further, thermal conductive silicon lipid layer can be folded with between cooler 1 and semiconductor chilling plate 2.That is, thermal conductive silicon lipid layer can be folded with between the another side of cooler 1 and the cold junction 21 of semiconductor chilling plate 2, the high and contact gap can filled between the another side of cooler 1 and the cold junction 21 of semiconductor chilling plate 2 of the thermal conductivity of thermal conductive silicon lipid layer.Thus, the rate of heat exchange between cooler 1 and semiconductor chilling plate 2 can be improved, and then the refrigerating speed of refrigerating plant 100 is promoted.

Cooler 1 can have various structures.In embodiment more of the present utility model, as shown in Figure 2, cooler 1 is suitable for coated cup, the such as squeezing cup 200 of coated juice extractor 1000 or the kettle body of kettle, be understandable that, cooler 1 can be configured to the structure similar to the shape of squeezing cup 200 or kettle body.The cold junction 21 of semiconductor chilling plate 2 can be fitted with the outer bottom of cooler 1.Thus, the contact area between cooler 1 and squeezing cup 200 or kettle body can be increased, accelerate the cold junction 21 of semiconductor chilling plate 2 and the rate of heat exchange of liquid in squeezing cup 200 or kettle body, and then optimize the refrigerating speed of refrigerating plant 100.

In other embodiment of the present utility model, as shown in Figure 6, cooler 1 can comprise cold scattering pedestal 11 and cold scattering fin 12, and the one side of cold scattering pedestal 11 is connected with cold scattering fin 12, and the another side of cold scattering pedestal 11 and the cold junction 21 of semiconductor chilling plate 2 are fitted.Cold scattering pedestal 11 is suitable for forming cup at least partially, such as cold scattering pedestal 11 is suitable at the bottom of at least part of glass of formation squeezing cup 200, cold scattering fin 12 is suitable for stretching into cup, such as, in the spatial accommodation of squeezing cup 200, or cold scattering pedestal 11 is suitable at least part of diapire forming kettle body, cold scattering fin 12 is suitable for stretching into cup, such as, in the spatial accommodation of kettle body.

Thus, cooler 1 can carry out heat exchange by the liquid directly and in squeezing cup 200 or kettle body, weaken squeezing cup 200 or kettle body to the negative effect of heat exchange, heat exchanger effectiveness between liquid in cooler 1 and squeezing cup 200 or kettle body is got a promotion, and then optimizes the refrigerating speed of refrigerating plant 100.

Semiconductor chilling plate 2 is folded between radiator 3 and cooler 1; in order to increase contact area between semiconductor chilling plate 2 and radiator 3 or cooler 1; need to apply pressure between three; and the compression strength of semiconductor chilling plate 2 is less; in order to prevent semiconductor chilling plate 2 crushed, the guard circle identical with its thickness can be arranged with on semiconductor chilling plate 2.

In sum, according to the refrigerating plant 100 for cooking apparatus of the utility model embodiment, comprise cooler 1, semiconductor chilling plate 2 and radiator 3, the cold junction 21 of semiconductor chilling plate 2 is fitted with the cold scattering pedestal 11 of cooler 1, fit with the cooling base 31 of radiator 3 in hot junction 22, and be all folded with thermal conductive silicon lipid layer between cold junction 21 and cold scattering pedestal 11 and between hot junction 22 and cooling base 31, cooling base 31 is connected with radiating fin 32, and blower fan 6 is just to radiating fin 32, cold scattering pedestal 11 is suitable at the bottom of at least part of glass of formation squeezing cup 200 or at least part of diapire of kettle body, cold scattering fin 12 is suitable for stretching in the spatial accommodation of squeezing cup 200 or kettle body.After semiconductor chilling plate 2 is energized, cold junction 21 and cooler 1 carry out heat exchange, cooler 1 carries out heat exchange with the liquid in squeezing cup 200 or kettle body, hot junction 22 and the radiator 3 of semiconductor chilling plate 2 carry out heat exchange, radiator 3 and environment carry out heat exchange, can realize the quick cooling of the liquid in squeezing cup 200 or kettle body thus.

In second preferred embodiment of the present utility model, as shown in figs 1 to 6, the refrigerating plant 100 for cooking apparatus comprises cooler 1, semiconductor chilling plate 2 and radiating module 10.Semiconductor chilling plate 2 mainly utilizes the Peltier effect of semi-conducting material to realize refrigeration, when the galvanic couple that direct current is connected into by two kinds of different semi-conducting materials, can absorb heat respectively and release heat, and maintain certain temperature difference at the two ends of galvanic couple.

Semiconductor chilling plate 2 comprises hot junction 22 and cold junction 21, can maintain certain temperature difference between hot junction 22 and cold junction 21.The hot junction 22 of semiconductor chilling plate 2 is connected with radiating module 10, to absorb the heat in the hot junction 22 of semiconductor chilling plate 2, reduces the temperature in the hot junction 22 of semiconductor chilling plate 2; The cold junction 21 of semiconductor chilling plate 2 is suitable for being connected with the another side of cooler 1, the one side of cooler 1 is suitable for and cup, the squeezing cup 200 of such as juice extractor 1000 is connected, with with liquid in squeezing cup 200 carry out heat exchange, or the one side of cooler 1 is suitable for being connected with the kettle body of kettle, to carry out heat exchange with liquid in kettle body.Like this, the cold junction 21 of semiconductor chilling plate 2 can from the liquid continuous absorption heat in the liquid in squeezing cup 200 or kettle body, to reduce fast in squeezing cup 200 or the temperature of liquid in kettle body.

The volume of the liquid of the cooling time of refrigerating plant 100 and refrigeration work consumption, needs refrigeration and need the temperature number form reduced to have functional relation: time=specific heat capacity × liquid volume (liter) × fluid density × cooling number of degrees ÷ refrigeration work consumption.Such as when refrigeration work consumption is 100W, lower the temperature 8 DEG C to the fruit juice of 500ml, required time was less than 3 minutes.

Further, as shown in Fig. 2-Fig. 3, radiating module 10 can comprise heat pipe 41 and fin 42.Heat pipe 41 utilizes medium phase transition process in other end condensation after one end evaporation in hot junction 22, and heat is conducted fast.Wherein one end of heat pipe 41 is connected with the hot junction 22 of semiconductor chilling plate 2, go out, and the other end of heat pipe 41 is arranged with fin 42 with the quick heat conduction by the hot junction 22 of semiconductor chilling plate 2, to make medium in the rapid condensation of the other end of heat pipe 41.Because heat pipe 41 has very high thermal conductivity, therefore, the temperature in the hot junction 22 of semiconductor chilling plate 2 can remain on lower level, thus, accelerates the cooling velocity of refrigerating plant 100.

In order to accelerate the heat conduction in the hot junction 22 of semiconductor chilling plate 2, heat pipe 41 can comprise multi coil bundle.

The tube bank that length is larger has good heat-conductive characteristic, and the shorter tube bundle heat response of length is very fast.Further, the length of multi coil bundle can be different.That is, heat pipe 41 comprises the short different tube bank of many platoon leaders, thus, has taken into account heat-conductive characteristic and the thermal response speed of heat pipe 41, and then optimizes the cooling effect of refrigerating plant 100.

Further, thermal conductive silicon lipid layer can be folded with between heat pipe 41 and semiconductor chilling plate 2.High and the contact gap between the hot junction 22 can filling heat pipe 41 and semiconductor chilling plate 2 of the thermal conductivity of thermal conductive silicon lipid layer.Thus, improve the rate of heat exchange between heat pipe 41 and semiconductor chilling plate 2, and then the refrigerating speed of refrigerating plant 100 is promoted.

As shown in Fig. 2-Fig. 3, it is thicker that fin 42 can be configured to middle part, the structure that edge is thinner, and the middle part of fin 42 is set on the other end of heat pipe 41.Thereby increase heat pipe 41 and the contact area of fin 42, make medium in the faster condensation of the other end of heat pipe 41.

Further, as shown in Fig. 2-Fig. 3, the refrigerating plant 100 for cooking apparatus can also comprise blower fan 6, and blower fan 6 is suitable for dispelling the heat to fin 42, to accelerate the heat loss of fin 42.In order to optimize the radiating effect of fin 42 further, as shown in Fig. 2-Fig. 3, the wind direction (as shown in the arrow A in Fig. 2 and Fig. 3) that blower fan 6 blows out can face fin 42.

The cold junction 21 of semiconductor chilling plate 2 is connected with squeezing cup 200 or kettle body by cooler 1.Cooler 1 can be alumiaum article, and the thermal conductivity of aluminium is good, and quality is light, and low price, be conducive to the weight alleviating refrigerating plant 100, reduce manufacturing cost.

Alternatively, cooler 1 can be copper fitting, and the thermal conductivity of copper and ductility are all good, according to the shape being made as needs better, promptly can carry out heat exchange with the cold junction 21 of semiconductor chilling plate 2, and then accelerates the refrigerating speed of refrigerating plant 100.

Further, thermal conductive silicon lipid layer can be folded with between cooler 1 and semiconductor chilling plate 2.That is, thermal conductive silicon lipid layer can be folded with between the another side of cooler 1 and the cold junction 21 of semiconductor chilling plate 2, the high and contact gap can filled between the another side of cooler 1 and the cold junction 21 of semiconductor chilling plate 2 of the thermal conductivity of thermal conductive silicon lipid layer.Thus, the rate of heat exchange between cooler 1 and semiconductor chilling plate 2 can be improved, and then the refrigerating speed of refrigerating plant 100 is promoted.

Cooler 1 can have various structures.In embodiment more of the present utility model, as shown in Figure 2, cooler 1 is suitable for coated cup, the such as squeezing cup 200 of coated juice extractor 1000 or the kettle body of kettle, be understandable that, cooler 1 can be configured to the structure similar to the shape of squeezing cup 200 or kettle body.The cold junction 21 of semiconductor chilling plate 2 can be fitted with the outer bottom of cooler 1.Thus, the contact area between cooler 1 and squeezing cup 200 or kettle body can be increased, accelerate the cold junction 21 of semiconductor chilling plate 2 and the rate of heat exchange of liquid in squeezing cup 200 or kettle body, and then optimize the refrigerating speed of refrigerating plant 100.

In other embodiment of the present utility model, as shown in Figure 6, cooler 1 can comprise cold scattering pedestal 11 and cold scattering fin 12, and the one side of cold scattering pedestal 11 is connected with cold scattering fin 12, and the another side of cold scattering pedestal 11 and the cold junction 21 of semiconductor chilling plate 2 are fitted.Cold scattering pedestal 11 is suitable for forming cup at least partially, such as cold scattering pedestal 11 is suitable at the bottom of at least part of glass of formation squeezing cup 200, cold scattering fin 12 is suitable for stretching into cup, such as, in the spatial accommodation of squeezing cup 200, or cold scattering pedestal 11 is suitable at least part of diapire forming kettle body, cold scattering fin 12 is suitable for stretching into cup, such as, in the spatial accommodation of kettle body.

Thus, cooler 1 can carry out heat exchange by the liquid directly and in squeezing cup 200 or kettle body, weaken squeezing cup 200 or kettle body to the negative effect of heat exchange, heat exchanger effectiveness between liquid in cooler 1 and squeezing cup 200 or kettle body is got a promotion, and then optimizes the refrigerating speed of refrigerating plant 100.

Semiconductor chilling plate 2 is folded between heat pipe 41 and cooler 1; in order to increase contact area between semiconductor chilling plate 2 and heat pipe 41 or cooler 1; need to apply pressure between three; and the compression strength of semiconductor chilling plate 2 is less; in order to prevent semiconductor chilling plate 2 crushed, the guard circle identical with its thickness can be arranged with on semiconductor chilling plate 2.

In sum, according to the refrigerating plant 100 for cooking apparatus of the utility model embodiment, comprise cooler 1, semiconductor chilling plate 2, heat pipe 41 and fin 42, the cold junction 21 of semiconductor chilling plate 2 is fitted with the cold scattering pedestal 11 of cooler 1, hot junction 22 and heat pipe 41 are fitted, and be all folded with thermal conductive silicon lipid layer between cold junction 21 and cold scattering pedestal 11 and between hot junction 22 and heat pipe 41, heat pipe 41 is arranged with fin 42, and blower fan 6 is just to fin 42, cold scattering pedestal 11 is suitable at the bottom of at least part of glass of formation squeezing cup 200 or at least part of diapire of kettle body, cold scattering fin 12 is suitable for stretching in the spatial accommodation of squeezing cup 200 or kettle body.After semiconductor chilling plate 2 is energized, cold junction 21 and cooler 1 carry out heat exchange, cooler 1 carries out heat exchange with the liquid in squeezing cup 200 or kettle body, hot junction 22 and the heat pipe 41 of semiconductor chilling plate 2 carry out heat exchange, the heat that fin 42 absorbs heat pipe 41 carries out heat exchange with environment again, can realize the quick cooling of the liquid in squeezing cup 200 or kettle body thus.

In the 3rd preferred embodiment of the present utility model, as shown in fig. 4-5, the refrigerating plant 100 for cooking apparatus comprises semiconductor chilling plate 2 and water-cooled assembly 5, and that is, in this embodiment, radiating module 10 comprises water-cooled assembly 5.Semiconductor chilling plate 2 mainly utilizes the Peltier effect of semi-conducting material to realize refrigeration, when the galvanic couple that direct current is connected into by two kinds of different semi-conducting materials, can absorb heat respectively and release heat, and maintain certain temperature difference at the two ends of galvanic couple.

Semiconductor chilling plate 2 comprises hot junction 22 and cold junction 21, can maintain certain temperature difference between hot junction 22 and cold junction 21.The cold junction 21 of semiconductor chilling plate 2 is suitable for being connected with the squeezing cup 200 of juice extractor 1000, and to reduce rapidly the temperature of liquid in squeezing cup 200, or the cold junction 21 of semiconductor chilling plate 2 is suitable for being connected with the kettle body of kettle, to reduce rapidly the temperature of liquid in kettle body; The hot junction 22 of semiconductor chilling plate 2 is connected with water-cooled assembly 5, to absorb the heat in the hot junction 22 of semiconductor chilling plate 2, reduces the temperature in the hot junction 22 of semiconductor chilling plate 2.Like this, the cold junction 21 of semiconductor chilling plate 2 can from the liquid continuous absorption heat in the liquid in squeezing cup 200 or kettle body, to reduce fast in squeezing cup 200 or the temperature of liquid in kettle body.

The volume of the liquid of the cooling time of refrigerating plant 100 and refrigeration work consumption, needs refrigeration and need the temperature number form reduced to have functional relation: time=specific heat capacity × liquid volume (liter) × fluid density × cooling number of degrees ÷ refrigeration work consumption.Such as when refrigeration work consumption is 100W, lower the temperature 8 DEG C to the fruit juice of 500ml, required time was less than 3 minutes.

Further, as shown in fig. 4-5, water-cooled assembly 5 can comprise cooling water tank 51, water pump 52 and radiating tube 53, and wherein cooling water tank 51 can be connected with the hot junction 22 of semiconductor chilling plate 2, to reduce the temperature in the hot junction 22 of semiconductor chilling plate 2.Cooling water tank 51, water pump 52 and radiating tube 53 can form cooling circuit, concrete connected mode is: the delivery port of water pump 52 is connected with the water inlet of cooling water tank 51, the water inlet of radiating tube 53 is connected with the delivery port of cooling water tank 51, and the delivery port of radiating tube 53 is connected with the water inlet of water pump 52.Heat exchange is carried out by the cooling fluid in the casing of cooling water tank 51 and cooling water tank 51 in the hot junction 22 of semiconductor chilling plate 2, cooling fluid in cooling water tank 51 flows into radiating tube 53 from the delivery port of cooling water tank 51 through the water inlet of radiating tube 53, heat exchange is carried out with external environment with cooled in radiating tube 53, cooling fluid cooled in radiating tube 53 flows into water pump 52 from the delivery port of radiating tube 53 through the water inlet of water pump 52, to enter in cooling water tank 51 through the water inlet of cooling water tank 51 from the delivery port of water pump 52 again and carry out heat exchange with the hot junction 22 of semiconductor chilling plate 2, the power that water pump 52 provides liquid circulation to flow.This cooling circuit constantly can absorb heat from the hot junction 22 of semiconductor chilling plate 2, realizes the fast-refrigerating of refrigerating plant 100 thus.

Further, between cooling water tank 51 and semiconductor chilling plate 2, thermal conductive silicon lipid layer can be folded with, the high and contact gap between the hot junction 22 can filling cooling water tank 51 and semiconductor chilling plate 2 of the thermal conductivity of thermal conductive silicon lipid layer.Thus, improve the rate of heat exchange between cooling water tank 51 and semiconductor chilling plate 2, and then the refrigerating speed of refrigerating plant 100 is promoted.

Optionally, as shown in fig. 4-5, cooling water tank 51, can be communicated with by pipeline 55 between water pump 52 and radiating tube 53.

Preferably, as shown in fig. 4-5, radiating tube 53 can form end to end U-shaped structure.

Further, water-cooled assembly 5 can also comprise cooling bath 54, fills cooling fluid in cooling bath 54, and radiating tube 53 is immersed in the cooling fluid of cooling bath 54.Thus, the cooling velocity of radiating tube 53 can be accelerated, and then the refrigerating speed of refrigerating plant 100 is promoted.

Further, as shown in fig. 4-5, the refrigerating plant 100 for cooking apparatus can also comprise blower fan 6, and blower fan 6 is suitable for dispelling the heat to cooling bath 54, to accelerate the heat loss of radiating tube 53.In order to optimize the radiating effect of water-cooled assembly 5 further.

The cold junction 21 of semiconductor chilling plate 2 is suitable for cooling the liquid in squeezing cup 200 or kettle body.Further, the refrigerating plant 100 for cooking apparatus can also comprise cooler 1, and the one side of cooler 1 is suitable for and cup, and such as squeezing cup 200 or kettle body are connected, and the another side of cooler 1 is connected with the cold junction 21 of semiconductor chilling plate 2.That is, the cold junction 21 of semiconductor chilling plate 2 is connected with squeezing cup 200 or kettle body by cooler 1, the cold junction 21 of the semiconductor chilling plate 2 that on the one hand temperature can be prevented too low damages squeezing cup 200 or kettle body, can optimize the heat exchanger effectiveness of semiconductor chilling plate 2 and liquid in squeezing cup 200 or kettle body on the other hand.

Cooler 1 can be alumiaum article, and the thermal conductivity of aluminium is good, and quality is light, and low price, be conducive to the weight alleviating refrigerating plant 100, reduce manufacturing cost.

Alternatively, cooler 1 can be copper fitting, and the thermal conductivity of copper and ductility are all good, according to the shape being made as needs better, promptly can carry out heat exchange with the cold junction 21 of semiconductor chilling plate 2, and then accelerates the refrigerating speed of refrigerating plant 100.

Further, thermal conductive silicon lipid layer can be folded with between cooler 1 and semiconductor chilling plate 2.That is, thermal conductive silicon lipid layer can be folded with between the another side of cooler 1 and the cold junction 21 of semiconductor chilling plate 2, the high and contact gap can filled between the another side of cooler 1 and the cold junction 21 of semiconductor chilling plate 2 of the thermal conductivity of thermal conductive silicon lipid layer.Thus, the rate of heat exchange between cooler 1 and semiconductor chilling plate 2 can be improved, and then the refrigerating speed of refrigerating plant 100 is promoted.

Cooler 1 can have various structures.In embodiment more of the present utility model, as shown in Figure 2, cooler 1 is suitable for coated cup, the such as squeezing cup 200 of coated juice extractor 1000 or the kettle body of kettle, be understandable that, cooler 1 can be configured to the structure similar to the shape of squeezing cup 200 or kettle body.The cold junction 21 of semiconductor chilling plate 2 can be fitted with the outer bottom of cooler 1.Thus, the contact area between cooler 1 and squeezing cup 200 or kettle body can be increased, accelerate the cold junction 21 of semiconductor chilling plate 2 and the rate of heat exchange of liquid in squeezing cup 200 or kettle body, and then optimize the refrigerating speed of refrigerating plant 100.

In other embodiment of the present utility model, as shown in Figure 6, cooler 1 can comprise cold scattering pedestal 11 and cold scattering fin 12, and the one side of cold scattering pedestal 11 is connected with cold scattering fin 12, and the another side of cold scattering pedestal 11 and the cold junction 21 of semiconductor chilling plate 2 are fitted.Cold scattering pedestal 11 is suitable for forming cup at least partially, such as cold scattering pedestal 11 is suitable at the bottom of at least part of glass of formation squeezing cup 200, cold scattering fin 12 is suitable for stretching into cup, such as, in the spatial accommodation of squeezing cup 200, or cold scattering pedestal 11 is suitable at least part of diapire forming kettle body, cold scattering fin 12 is suitable for stretching into cup, such as, in the spatial accommodation of kettle body.

Thus, cooler 1 can carry out heat exchange by the liquid directly and in squeezing cup 200 or kettle body, weaken squeezing cup 200 or kettle body to the negative effect of heat exchange, heat exchanger effectiveness between liquid in cooler 1 and squeezing cup 200 or kettle body is got a promotion, and then optimizes the refrigerating speed of refrigerating plant 100.

Semiconductor chilling plate 2 is folded between radiator 3 and cooler 1; in order to increase contact area between semiconductor chilling plate 2 and radiator 3 or cooler 1; need to apply pressure between three; and the compression strength of semiconductor chilling plate 2 is less; in order to prevent semiconductor chilling plate 2 crushed, the guard circle identical with its thickness can be arranged with on semiconductor chilling plate 2.

In sum, according to the refrigerating plant 100 for cooking apparatus of the utility model embodiment, comprise cooler 1, semiconductor chilling plate 2 and water-cooled assembly 5, the cold junction 21 of semiconductor chilling plate 2 is fitted with the cold scattering pedestal 11 of cooler 1, fit with the cooling water tank 51 of water-cooled assembly 5 in hot junction 22, and be all folded with thermal conductive silicon lipid layer between cold junction 21 and cold scattering pedestal 11 and between hot junction 22 and cooling water tank 51, cooling water tank 51 and form cooling circuit between water pump 52 and radiating tube 53 with the heat in constant absorption hot junction 22, cold scattering pedestal 11 is suitable at the bottom of at least part of glass of formation squeezing cup 200 or at least part of diapire of kettle body, cold scattering fin 12 is suitable for stretching in the spatial accommodation of squeezing cup 200 or kettle body.After semiconductor chilling plate 2 is energized, cold junction 21 and cooler 1 carry out heat exchange, cooler 1 carries out heat exchange with the liquid in squeezing cup 200 or kettle body, hot junction 22 and the cooling water tank 51 of semiconductor chilling plate 2 carry out heat exchange, cooling water tank 51 carries out heat exchange by cooling circuit and environment, can realize the quick cooling of the liquid in squeezing cup 200 or kettle body thus.

According to the juice extractor 1000 of the utility model embodiment, comprise the refrigerating plant 100 for cooking apparatus that above-described embodiment describes.

As shown in Figure 2 and Figure 5, cooking apparatus is juice extractor 1000 such as, temperature-detecting device 400 and controller 600 can also be comprised, temperature-detecting device 400 can be arranged on cup, such as, on the wall of cup of squeezing cup 200 or bottom, controller 600 is connected with temperature-detecting device 400, and controller 600 is also connected with refrigerating plant 100, thus controller 600 can control the start and stop of refrigerating plant 100 according to the temperature detection value of temperature-detecting device 400.

Specifically, take cooking apparatus as juice extractor 1000 be example, refrigerating fresh-keeping pattern can be selected after user's squeezed juice completes, refrigerating plant 100 is selected to start work, the fruit juice that squeezing cup is 200 li or the Other Drinks that user puts in start refrigeration cool-down, temperature-detecting device 400 is the detecting fruit juice of squeezing cup 200 li or the temperature of Other Drinks constantly, after reaching target temperature, refrigerating plant 100 quits work, when detecting fruit juice or Other Drinks temperature is greater than the target temperature of user's setting, such as more than 1 degree or other error temperature of design time, again start refrigerating plant 100, until temperature reaches target temperature, repeatedly reach the object of long-time refrigerating fresh-keeping fruit juice according to this.

Use this juice extractor 1000 with facilitate realize long-time storage fruit juice while the effect of frozen juice also can be provided, separate refrigeration user can certainly be placed on separately Other Drinks (as pure water, cola, soya-bean milk, milk etc.) inside squeezing cup 200, meet the many-sided refrigeration demand of user, reach fresh-keeping while freezing function is also provided.

Alternatively, temperature-detecting device 400 can be temperature sensor.

Further, cooking apparatus can be juice extractor 1000, and spiral propeller 300 can also be comprised, spiral propeller 300 can be connected to be suitable for driving cup with the motor shaft 400 of juice extractor 1000, such as, liquid flow in squeezing cup 200, in the process that refrigerating plant 100 works, by opening spiral propeller 300, make the liquid in squeezing cup 200 be in flow regime, can refrigerating speed be accelerated thus.

With reference to shown in Fig. 7, juice extractor 1000 can comprise shell 710, power panel 720, net-filter assembly 730, motor 740, stick pusher 750 and residue receiving cup 760, stick pusher 750 is the entrance of fruit chunk, net-filter assembly 730 filters the fruit juice squeezed, motor 740 is responsible for being with dynamic spiral propeller 300 to rotate by motor shaft 500 and is carried out press juice, power panel 720 is responsible for powering to motor 740 and controller 600, controller 600 can comprise control panel, thus be responsible for the mode of operation controlling juice extractor 1000, such as refrigerating fresh-keeping, automatic cleaning, to squeeze the juice beginning, stop waiting operation to control.Shell 710 makes juice extractor 1000 outward appearance more attractive in appearance as the exterior structure part of juice extractor 1000, and can be used as the installation carrier of all parts of juice extractor 1000.Marc after spiral propeller 300 pairs of fruit chunks have squeezed fruit juice accesses placement by residue receiving cup 760.

According to the juice extractor 1000 of the utility model embodiment, the liquid of squeezing out can be cooled fast, easy to use.

According to the kettle of the utility model embodiment, comprise the refrigerating plant 100 for cooking apparatus that above-described embodiment describes, can liquid in rapid cooling water kettle, easy to use.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, to the schematic representation of above-mentioned term not must for be identical embodiment or example.And the specific features of description, structure, material or feature can combine in one or more embodiment in office or example in an appropriate manner.In addition, when not conflicting, the feature of the different embodiment described in this description or example and different embodiment or example can carry out combining and combining by those skilled in the art.

Although illustrate and described embodiment of the present utility model above, be understandable that, above-described embodiment is exemplary, can not be interpreted as restriction of the present utility model, those of ordinary skill in the art can change above-described embodiment, revises, replace and modification in scope of the present utility model.

Claims (12)

1. for a refrigerating plant for cooking apparatus, it is characterized in that, described cooking apparatus comprises juice extractor or kettle, and described refrigerating plant comprises:

Semiconductor chilling plate, the cold junction of described semiconductor chilling plate is suitable for being connected with the kettle body of the squeezing cup of described juice extractor or described kettle;

Radiator, described radiator is connected with the hot junction of described semiconductor chilling plate.

2. the refrigerating plant for cooking apparatus according to claim 1, is characterized in that, described radiator comprises:

Cooling base, the one side of described cooling base is fitted with described hot junction;

Radiating fin, described radiating fin is connected with the another side of described cooling base.

3. the refrigerating plant for cooking apparatus according to claim 2, is characterized in that, described radiator is alumiaum article or copper fitting.

4. the refrigerating plant for cooking apparatus according to claim 2, is characterized in that, also comprise:

Blower fan, described blower fan is suitable for described radiator heat-dissipation.

5. the refrigerating plant for cooking apparatus according to claim 2, is characterized in that, also comprise:

Cooler, the one side of described cooler is suitable for being connected with described squeezing cup or described kettle body and another side is connected with described cold junction.

6. the refrigerating plant for cooking apparatus according to claim 5, is characterized in that, is all folded with thermal conductive silicon lipid layer between described radiator and described semiconductor chilling plate and between described cooler and described semiconductor chilling plate.

7. the refrigerating plant for cooking apparatus according to claim 5, is characterized in that, described cooler is suitable for the squeezing cup of coated described juice extractor or the kettle body of described kettle, and the outer bottom of described cold junction and described cooler is fitted.

8. the refrigerating plant for cooking apparatus according to claim 5, is characterized in that, described cooler comprises:

Cold scattering pedestal and cold scattering fin, described cold scattering fin is connected with the one side of described cold scattering pedestal, and described cold scattering fin is suitable for stretching in the spatial accommodation of described squeezing cup or described kettle body, another side and the described cold junction of described cold scattering pedestal are fitted, and described cold scattering pedestal is suitable for forming at the bottom of at least part of glass of described squeezing cup or at least part of diapire of described kettle body.

9. the refrigerating plant for cooking apparatus according to any one of claim 2-8, is characterized in that, described semiconductor chilling plate is arranged with the guard circle identical with its thickness.

10. a juice extractor, is characterized in that, comprises the refrigerating plant for cooking apparatus according to any one of claim 1-9.

11. juice extractors according to claim 10, is characterized in that, also comprise:

Spiral propeller, described spiral propeller is connected with the motor shaft of described juice extractor to be suitable for driving the liquid flow in described squeezing cup.

12. 1 kinds of kettles, is characterized in that, comprise the refrigerating plant for cooking apparatus according to any one of claim 1-9.