CN219924081U - Heating type garbage disposer - Google Patents

Abstract

The utility model provides a heating type garbage disposer, including organism, lid, locate slip joint structure, elastic component in the organism, connect in first seal structure and second seal structure, heating element, condensation subassembly and water receiving container at elastic component both ends, first seal structure and slip joint structure sliding fit and its top support press fit with the bottom of lid under the effect of elastic component, be equipped with first passageway in the first seal structure, be equipped with the second passageway in the second seal structure, the elastic component has the cavity passageway of intercommunication first passageway and second passageway; the condensation assembly is provided with a guiding structure for guiding condensed water to the first channel. Compared with the prior art, the heating type garbage disposer has the advantages that the pressing effect between the first sealing structure and the cover body is improved under the action of the elastic piece by utilizing the downward pressure applied by the cover body to the first sealing structure, the sealing performance of a drainage channel between the first sealing structure and the cover body is improved, and meanwhile, the connection stability of the second sealing structure is also improved.

Description

Heating type garbage disposer

Technical Field

The utility model relates to the technical field of garbage disposers, in particular to a heating type garbage disposer.

Background

The heating type garbage disposer can grind larger garbage, and simultaneously evaporate water in the garbage to dry so as to realize garbage disposal.

In the existing garbage disposer, a channel for the outflow of condensed water formed by condensing and liquefying vapor flow is generally provided, for example, an authorized publication number CN215032265U provides a household garbage grinding and sterilizing device, wherein a distilled water box is arranged on a machine body, a filter element is arranged on a flip cover, and vapor passes through the filter element and then is condensed into the distilled water box, i.e. the channel for circulating the condensed water is communicated with the flip cover and the machine body. However, the existing structure of the circulation channel for forming condensed water is complex, and the difficulty of production, manufacture and assembly is high and the cost is high.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art and provides a heating type garbage disposer.

To achieve the above object, the present utility model discloses a heating type garbage disposer, comprising:

the garbage disposal device comprises a machine body and a cover body, wherein the cover body is detachably arranged on the machine body, and a garbage disposal cavity for disposing garbage is formed between the machine body and the cover body;

a sliding connection structure arranged in the machine body;

the elastic piece, connect to the first seal structure of one end of the elastic piece and connect to the second seal structure of another end of the elastic piece, the said first seal structure is in sliding fit with sliding connection structure and its top supports the press fit with the bottom of the cover under the function of the elastic piece, there are first channels in the said first seal structure, there are second channels in the said second seal structure, the said elastic piece has hollow channels which communicate the said first channel and second channel;

the heating component is arranged in the garbage treatment cavity and is used for evaporating water in the garbage to form water vapor;

the condensing assembly is used for condensing and liquefying the water vapor into condensed water and is provided with a guide structure for guiding the condensed water to the first channel;

and the water receiving container is communicated with the second channel.

Preferably, the condensing unit includes a condensing plate, a surface of the condensing plate adjacent to the heat generating unit serves as a condensing surface for condensing and liquefying the water vapor, and the condensing surface is gradually concave inward from a peripheral side thereof to an inner side thereof to form a guiding surface for guiding the condensed water flow to the first passage under the action of gravity, and the guiding surface is the guiding structure.

Preferably, the device further comprises a water collecting piece for collecting the condensed water, and a water outlet communicated with the first channel is arranged at the bottom of the water collecting piece.

Further preferably, the water collecting piece is arranged at the bottom of the cover body, and when the cover body is covered on the machine body, the bottom of the water collecting piece is in pressing fit with the end part, far away from the elastic piece, of the first sealing structure.

Preferably, the garbage treatment cavity, the first sealing structure, the elastic piece, the second sealing structure and the water receiving container are communicated to form a sealing space, and the condensing assembly condenses and liquefies the water vapor so as to control the pressure in the sealing space to be in a range of 0-34 kPa.

It is further preferable that the ratio between the amount of the condensed water per unit time of the condensing unit and the amount of the evaporated heat generating unit per unit time is 0.3 to 1 so as to achieve the control of the pressure.

Further preferably, an inner wall is arranged in the sliding connection structure to divide the sliding connection structure into a filter cavity close to the outer side and a hollow installation cavity, filter materials are arranged in the filter cavity, the upper end and the lower end of the installation cavity are communicated, and an air leakage channel is arranged between the filter cavity and the sealing space.

Further preferably, a water blocking member is arranged at the end of the air leakage channel, which is close to the elastic member, and a gap exists between the water blocking member and the air leakage channel.

Further preferably, the first sealing structure and the second sealing structure are in sealing fit with the mounting cavity, the elastic piece is provided with a communication channel which is communicated with the hollow channel and the mounting cavity, the inner wall is provided with an air passing hole which is communicated with the filter cavity and the mounting cavity, and the communication channel and the air passing hole are used as air leakage channels;

when the cover body is covered on the machine body, the air passing hole is higher than the lowest position of the first channel, and the first sealing structure is used as a water retaining member.

Preferably, the sliding connection structure comprises a box body and a box cover, a through hole is formed in the bottom of the box body, a connecting lug extending outwards is arranged at the top of the second sealing structure, the connecting lug is arranged at the edge of the top of the through hole, an inner wall extending towards the bottom of the box body is arranged on the cover body, the first sealing structure is in sliding fit with the inner wall, and the bottom of the inner wall is in abutting fit with the connecting lug;

the inner wall is equipped with the block, the tip that the elastic component kept away from first seal structure is located on the block.

Preferably, a limiting part is arranged in the machine body, and when the cover body covers the machine body, the first sealing structure abuts against the limiting part under the action of the elastic part.

Preferably, the machine body is provided with a containing space, the water receiving container is arranged in the containing space, the second sealing structure is an elastic sealing ring, and the bottom of the second sealing structure stretches into the containing space and abuts against the water receiving container.

When the heating type garbage disposer is used, the cover body is covered on the machine body, the first sealing structure slides downwards, the elastic piece is in a compressed state, and the first sealing structure and the cover body are mutually abutted under the action of the elastic piece, so that the sealing communication of the first sealing structure and the cover body is realized. The second sealing structure can also realize tight connection under the action of the elastic piece, so that the connection stability of the second sealing structure and the water receiving container is ensured.

Compared with the prior art, the utility model has the beneficial effects that: the garbage disposer makes the elastic piece in a compressed state or compressed further by utilizing the downward pressure applied by the cover body to the first sealing structure, so that the pressing effect between the first sealing structure and the cover body is further improved, the sealing performance of the drainage channel between the first sealing structure and the cover body is improved, and meanwhile, the connection stability of the second sealing structure is also improved. In addition, the sealing of the drainage channel is realized through the cooperation of the first sealing structure, the elastic piece and the cover body, and the structure is simple, and the production, the manufacturing and the assembly are convenient.

Drawings

FIG. 1 is one of the sectional views of the garbage disposer in example 1;

FIG. 2 is an enlarged schematic view of a portion of FIG. 1 at A;

FIG. 3 is a second cross-sectional view of the garbage disposer of example 1;

FIG. 4 is an enlarged partial schematic view at B in FIG. 3;

FIG. 5 is one of the sectional views of the garbage disposer in example 3;

FIG. 6 is a second cross-sectional view of the garbage disposer in example 3;

FIG. 7 is a third cross-sectional view of the waste disposer in example 3;

FIG. 8 is a fourth cross-sectional view of the garbage disposer of example 3;

FIG. 9 is a fifth cross-sectional view of the garbage disposer in example 3;

FIG. 10 is a sixth cross-sectional view of the garbage disposer of example 3;

FIG. 11 is one of the sectional views of the garbage disposer in example 4;

FIG. 12 is a second cross-sectional view of the garbage disposer of example 4;

FIG. 13 is a third cross-sectional view of the disposer in example 4;

a body 10; an inner container 11; a cutter head assembly 12; an elastic member 13; a first sealing structure 14; a first channel 141; a second sealing structure 15; a second channel 151; a connecting ear 152; the accommodating space 16; a first pipe 17; a second conduit 18; a hollow passage 19; a stopper 1010;

a cover 20; a pressing plate 21; a deflector swash plate 22; a first seal 23; an input tube 24; a return pipe 25; a shower pipe 26;

a heat generating component 30;

a condensing assembly 40; a condensing plate 41; a condensing surface 411; a guide surface 412; a pressing portion 4121; a non-condensing surface 413; a condensing space 42; a separator 421; a first space 422; a second space 423; a power device 43; an air blowing device 44;

a water receiving container 50; a water inlet 51;

a waste disposal chamber 60;

a water inlet channel 70; a drain passage 71; a water collecting member 72; a water outlet 721; a water outlet pipe 722;

a blow-by gas passage 80;

a slip-on structure 90; an inner wall 91; a clamping table 911; a gas passing hole 92; a filter chamber 93; a mounting cavity 94; an air outlet 95; a case 96; a lid 97;

a coolant tank 100; spray holes 101.

Detailed Description

In the description of the present utility model, it should be understood that the orientation or positional relationship indicated by the terms "inner", "outer", etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and include, for example, either fixedly attached, detachably attached, or integrally formed; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

The technical scheme of the utility model is further described below with reference to fig. 1-13.

Example 1

Referring to fig. 1, a heating type garbage disposer includes a body 10, a cover 20, a heating assembly 30, a condensing assembly 40, and a water receiving container 50. Wherein, the cover 20 is arranged on the machine body 10, and a garbage disposal cavity 60 for disposing garbage is formed between the machine body 10 and the cover 20. The water receiving container 50 is provided with a water inlet channel 70 positioned below the condensing assembly 40, and the water receiving container 50 is used for receiving and storing condensed water formed by condensing and liquefying the condensing assembly 40 through the water inlet channel 70 under the action of gravity; the water receiving container 50 is configured to communicate with the waste treatment chamber 60 to form a sealed space. The heating assembly 30 is disposed within the waste treatment chamber 60 for evaporating moisture from the waste. The condensing assembly 40 is used for condensing and liquefying the water vapor into condensed water, so as to control the pressure in the garbage disposal cavity 60 to be in the range of 0kPa to 34 kPa.

In use, the heating assembly 30 heats and evaporates the moisture of the waste in the waste treatment chamber 60, the water vapor is liquefied by the condensing assembly 40, and the condensed water flows into the water receiving container 50 through the water inlet channel 70 under the action of gravity. The space formed between the garbage treatment cavity 60 and the water collecting container is set as a sealing space, so that odor in the garbage treatment cavity is not easy to leak to the outside, the problem that the odor pollutes the outside air is effectively relieved, and the use effect of the garbage disposer is improved. In addition, in the use, under the effect of the heating component 30, the pressure in the garbage treatment cavity 60 becomes large, if the garbage treatment cavity 60 keeps large pressure, the pressure difference between the garbage treatment intensity and the outside becomes large, the sealing structure forming the sealing space is easy to damage, and the problem of odor leakage can occur after long-term use. In addition, in the actual use process, if a large pressure difference exists between the sealed space and the outside, the pressure balance between the sealed space and the outside can be maintained through a small gap generated by the manufacturing tolerance and the assembly tolerance of the self structure of the garbage disposer. Since the sealing space, the heating assembly 30 and the condensing assembly 40 are combined to limit most of the bad smell in the sealing space, the bad smell leaked from the above-mentioned gap does not pollute the external air, which ensures the use effect of the garbage disposer.

Wherein, the ratio between the condensation water quantity of the condensation component 40 in unit time and the evaporation quantity of the heating component 30 in unit time is 0.3-1, thus controlling the pressure intensity in the strong garbage treatment to be 0 kPa-34 kPa, limiting the odor in the sealed space and ensuring the use effect of the garbage treatment device. It should be noted that, the power of the heating element 30 of the heating garbage disposer is different, and the condensation rate of the condensation element 40 should be set within the corresponding interval range, so that the condensation water amount of the condensation element 40 per unit time and the evaporation amount of the heating element 30 per unit time are controlled within 0.3-1.

Referring to fig. 1, a liner 11 is disposed in a machine body 10, and when a cover 20 is covered on the machine body 10, the liner 11 and the cover 20 form the above-mentioned airtight garbage disposal chamber 60. The heat generating component 30 is preferably a heat generating plate, which is located at the bottom inside the inner container 11. The inner container 11 is also provided with a cutter head assembly 12 for crushing garbage. The structure of the above heating assembly 30 and the cutter head assembly 12 are conventional structures, which are conventional in the art, and will not be described herein.

Referring to fig. 1, the water inlet channel 70 has a gas conduction blocking structure, and the gas conduction blocking structure blocks water vapor by using water as an elastic switch (the condensed water is adopted as the elastic switch in the embodiment), so that the condensed water passes through normally. Under the condition that the condensed water can normally flow to the water receiving container 50 through the water inlet channel 70, the condensed water is used as an elastic switch to divide the garbage treatment cavity 60 and the water receiving container 50 into two spaces which are not communicated with each other or are not communicated with each other in most part (namely, the space which is communicated with the two spaces is provided with a small part by the air conduction blocking structure), and the odor is blocked by the condensed water of the air conduction blocking structure, so that the odor is limited in the closed garbage treatment strong, the leakage amount of the odor through the assembly gaps of the water inlet channel 70 and the water receiving container 50 is further reduced, and the use effect of the garbage treatment device is improved.

Referring to fig. 1-2, as a preferred embodiment of the air conduction blocking structure: the water inlet passage 70 is provided with a water discharge passage 71 and a water collecting member 72 for collecting condensed water, the bottom of the water collecting member 72 is provided with a water outlet 721, and the water discharge passage 71 is used for communicating the water outlet 721 to the water receiving container 50. The air conduction blocking structure is configured as a proportional relationship between the condensation rate of the condensation assembly 40 and the drainage rate of the water outlet 721, and the proportional relationship is used for enabling the condensed water to submerge the water outlet 721 under a normal condition (in the process that the water collecting piece 72 flows into the drainage channel 71 through the water outlet 721), so that the blocking of the condensed water to the water vapor is realized, the odor is limited in the garbage disposal cavity 60, and the use effect of the garbage disposal cavity 60 is ensured.

In this embodiment, the water collecting member 72 has a groove structure with an opening at the top, and the opening of the water collecting member 72 is directed to the position where the condensed water is dropped from the condensation assembly 40 so as to collect water; the water outlet 721 is disposed at the bottom of the trough-like structure. Of course, the water collection member 72 may be provided in other specific structural shapes.

Among these, there are two states in which the condensed water floods the water outlet 721, one is that the condensed water floods the water outlet 721 completely, and one is that the condensed water partially floods the water outlet 721, and the portion of the water outlet 721 not floods can enable the gas to flow through the drainage channel 71. In order to allow the water outlet 721 to completely or largely submerge the water outlet 721, the ratio of the condensation rate of the condensation assembly 40 to the drainage rate of the water outlet 721 is between 0.01 and 1, and preferably, the cross-sectional area of the water outlet 721 is between 1 and 3000mm ² . Thus, most of odor can be limited in the garbage disposal cavity 60 by the condensed water, so that the strong use effect of garbage disposal is greatly ensured.

Referring to fig. 1, the condensing unit 40 includes a condensing plate 41, a surface of the condensing plate 41 adjacent to the heat generating unit 30 serves as a condensing surface 411 for condensing the liquefied water vapor, and the condensing surface 411 has a concave groove structure, which has a guiding surface 412 gradually concave inward from an outer periphery thereof to an inner side for guiding the condensed water to the water inlet channel 70 under the action of gravity, and in this embodiment, the condensing surface 411 is the guiding surface 412. The condensation surface 411 forms an upper wall of the waste treatment chamber 60, which forms with the water collector 72 a guiding structure for guiding condensed water on the condensation surface 411 to the drain channel 71. The upper wall of the garbage disposer is set as the condensing surface 411 of the condensing plate 41, so that the condensing surface 411 has a larger condensing surface 411 area on the basis of condensing and liquefying, the condensing rate is ensured, and the water outlet 721 of the water collecting piece 72 can be further submerged by the condensing water. In addition, the condensation surface 411, which is gradually recessed from the outer circumference side to the inner side, can condense the liquefied water vapor to form condensed water, and can guide the condensed water at the same time, and has a simple and compact structure. The opening of the water collecting member 72 is directed to the outer circumferential side of the condensation module 40, so that the condensed water is condensed and liquefied on the condensation surface 411, and then the condensed water can be collected to the outer circumferential side thereof and then dropped onto the water collecting member 72.

Referring to fig. 1, the condensation surface 411 is located above the heating component 30, and the two positions are opposite, so that when the moisture in the garbage is evaporated by the heating component 30, the water vapor can rise to the condensation surface 411 of the condensation plate 41 to be condensed, so that the condensation efficiency is greatly improved, and the water outlet 721 of the water collecting member 72 can be further submerged by the condensation water.

Referring to fig. 1, the condensation plate 41 is connected to the bottom of the cover 20, and the condensation surface 411 is the bottom surface of the cover 20, when the cover 20 is covered on the machine body 10, the condensation surface 411 forms the upper wall of the garbage disposal chamber 60, so that energy loss caused by heat transfer between the condensation assembly 40 and the heating assembly 30 is avoided, and the heating effect and the condensation effect are ensured.

Referring to fig. 1-2, the outer peripheral side of the guide surface 412 is bent outward to form a horizontally disposed pressing portion 4121, and the cover 20 is detachably connected with a pressing plate 21 below the pressing portion 4121, and the pressing plate 21 is connected below the pressing portion 4121 and abuts against the pressing portion 4121 to fix the condensing plate 41 to the bottom of the cover 20. The pressing plate 21 is provided with a first sealing member 23, the first sealing member 23 may be an O-ring, and the first sealing member 23 seals against the pressing portion 4121 and the pressing plate 21, so as to ensure sealing performance between the pressing portion 4121 and the pressing plate 21.

Referring to fig. 1-2, when the condensed water is drained to the pressing portion 4121, the condensed water will adhere to the bottom surface of the pressing portion 4121 because the bottom surface of the pressing portion 4121 is a horizontal surface, and the condensed water is difficult to form water drops at the position of the pressing portion 4121, so as to reduce the speed of the condensed water dropping to the water collecting member 72, and affect the water outlet 721 of the condensed water flooding the water collecting member 72. Based on this, the end of the pressing plate 21 near the condensing plate 41 is bent to form the guiding inclined plate 22, the guiding inclined plate 22 is inclined to the water collecting piece 72, when the condensed water is guided to the bottom surface of the pressing portion 4121, the condensed water is continuously guided to the end of the guiding inclined plate 22 far away from the pressing portion 4121 by the guiding inclined plate 22, and under the action of gravity, the condensed water drops into the water collecting piece 72 in a water drop manner. By arranging the diversion sloping plate 22, when the condensed water flows to the end part of the diversion sloping plate 22 far away from the pressing part 4121, the condensed water can drop into the water collecting piece 72 under the action of gravity, so that the dropping speed of the condensed water is accelerated, the water outlet 721 of the water collecting piece 72 is ensured to be submerged by enough condensed water, more odor is limited in the garbage disposal cavity 60, and the use effect is ensured. In addition, when the garbage disposer just enters into a working state, the flow guiding inclined plate 22 quickens the dripping of the condensed water, so that the condensed water can quickly submerge the water outlet 721 of the water collecting piece 72, and the odor blocking effect is improved.

Referring to fig. 2, the end of the deflector plate 22 remote from the condensing plate 41 and the inlet of the water inlet passage 70 are sequentially disposed in the flow direction from the waste treatment chamber 60 to the water receiving container 50 and are offset from each other. In this way, in the process that the condensed water forms water drops at the end of the diversion sloping plate 22 away from the pressing part 4121, the water drops hang on the diversion sloping plate 22, which reduces the gap between the pressing part 4121 and the diversion sloping plate 22, so that less odor flows through the gap and the rear channel, the odor is further limited in the garbage disposal cavity 60, and the use effect of the garbage disposal is improved.

Referring to fig. 1 and 3, in the present embodiment, a drain passage 71 between the air passage blocking structure and the water receiving container 50 has an air leakage passage 80, and the structure and position of the air leakage passage 80 are described below. The disposer also includes a slip-on structure 90 in communication with the leak path 80. When the inside of the garbage disposal cavity 60 is up to a certain threshold value, the odor leaked from the air leakage channel 80 is filtered and deodorized by the sliding connection structure 90 and then discharged to the outside, and the user can not smell the odor basically under the working condition, so that the deodorizing effect and the using effect are further improved. In order to prevent condensed water in the drainage channel 71 from entering the sliding connection structure 90 through the air leakage channel 80, and to influence the use effect of the sliding connection structure 90, a water blocking member is arranged at the end of the drainage channel 71 close to the air leakage channel 80, and the water blocking member can block the inlet of the air leakage channel 80, so that condensed water in the drainage channel 71 is prevented from entering the sliding connection structure 90 through the air leakage channel 80. A gap exists between the water blocking piece and the air leakage channel 80, so that air can enter the air leakage channel 80 and then enter the sliding connection structure 90 for filtering and deodorizing.

Specifically, referring to fig. 1 to 4, the cover 20 is detachably sealed on the body 10, the water collecting member 72 is detachably disposed at the bottom of the cover 20 and below the inclined flow guiding plate 22, the water draining channel 71 is disposed in the body 10, and when the cover 20 is covered on the body 10, the water outlet 721 of the water collecting member 72 is in sealing communication with the water draining channel 71. In this embodiment, the sliding connection structure 90 is a filter, specifically, the sliding connection structure 90 is provided with an inner wall 91 so as to divide the sliding connection structure 90 into a filter cavity 93 near the outer side and a hollow installation cavity 94; the filter cavity 93 is provided with a filter medium, which can be preferably activated carbon, and of course, filter cotton or other filter media can be selected; the side of the filter cavity 93 away from the mounting cavity 94 is provided with an air outlet 95, and the filtered air flows out to the outside through the air outlet 95; the upper and lower ends of the installation chamber 94 are communicated for installing a structure forming the drainage channel 71, and the inner wall 91 is provided with a gas passing hole 92.

The machine body 10 is internally provided with an elastic piece 13, a first sealing structure 14 connected to the upper end of the elastic piece 13 and a second sealing structure 15 connected to the lower end of the elastic piece 13; the first sealing structure 14 is partially positioned in the mounting cavity 94, and partially extends to the upper side of the mounting cavity 94 to be in abutting press fit with the bottom of the water collecting piece 72, a first channel 141 is arranged in the first sealing structure 14, and the outer wall of the first channel is in sliding and sealing fit with the mounting cavity 94; the second sealing structure 15 is positioned at the bottom of the mounting cavity 94, and is provided with a second channel 151 therein, which is also in sealing fit with the mounting cavity 94; the elastic member 13 is located in the installation cavity 94 and has a hollow passage 19 communicating with the first passage 141 and the second passage 151, and the elastic member 13 is further provided with a communication passage communicating with the hollow passage 19 and the installation cavity 94, and the air passing hole 92 and the communication passage form the above-mentioned air leakage passage 80. In the present embodiment, the elastic member 13 is preferably a spring. The first channel 141, the hollow channel 19 (i.e. the space of the mounting cavity 94 between the bottom of the first channel 141 and the top of the second channel 151), the second channel 151, form the drain channel 71. The first sealing structure 14 is in sealing fit with the second sealing structure 15, the drainage channel 71 in the installation cavity 94 forms a sealed channel, odor is not easy to leak in the channel, and the use effect of the garbage disposer is ensured; the outer wall of the first sealing structure 14 is slidably matched with the mounting cavity 94, so that after the cover body 20 is covered on the machine body 10, the bottom of the water collecting piece 72 is pressed down to tightly press the first sealing structure 14 (at the moment, the elastic piece 13 is in a compressed state), which can not only communicate the water outlet 721 of the water collecting piece 72 with the water drainage channel 71, but also improve the sealing performance between the water collecting piece 72 and the water drainage channel 71 and reduce odor leakage; in addition, when the first sealing structure 14 is pressed down, under the action of the elastic member 13, the end portion of the second sealing structure 15 away from the elastic member 13 abuts against the water inlet 51 of the water container 50 so as to enable the second channel 151 to be in sealing communication with the water receiving container 50, and the air passing hole 92 is located in a sealing space formed by the first sealing structure 14 and the second sealing structure 15 and the installation cavity 94.

Referring to fig. 2, a limiting member 1010 is disposed in the machine body 10, and the limiting member 1010 is located above the sliding structure 90 with a certain distance therebetween. When the cover 20 is opened, the first sealing structure 14 abuts against the limiting member 1010 under the action of the elastic member 13, so as to ensure the assembly stability of the first sealing structure 14. When the cover 20 is opened, the elastic member 13 may be in a normal state or a compressed state, and in this embodiment, in order to improve the assembly stability, the elastic member is in a compressed state.

Referring to fig. 2, the bottom of the water outlet 721 of the water collecting member 72 is provided with a water outlet conduit 722 extending downward so as to press against the top of the first sealing structure 14 when the cover 20 is covered on the body 10. Of course, the top of the first sealing structure 14 may also be extended above the stopper 1010, so that the bottom of the water collecting piece 72 presses down the first sealing structure 14.

Referring to fig. 1, the sliding connection structure 90 includes a box body 96 and a box cover 97 that are detachably connected, a through hole is formed at the bottom of the box body 96, an outwardly extending connection lug 152 is disposed at the top of the second sealing structure 15, the connection lug 152 is mounted at the top edge of the through hole, the bottom of the cover 20 is provided with the inner wall 91, and when the box cover 97 is mounted on the box body 96, the bottom of the inner wall 91 abuts against the connection lug 152 of the second sealing structure 15. The inner wall 91 is provided with a clamping platform 911, and the end of the elastic member 13 remote from the first sealing structure 14 is arranged on the clamping platform 911. When the cover 97 is connected to the case 96 and is mounted with the elastic member 13, the first sealing structure 14 and the second sealing structure 15, the elastic member 13 provides an elastic force to the clamping platform 911, and the force not only enables the cover 97 to cover the case 96 more stably, but also enables the inner wall 91 of the cover 97 to abut against the connecting lug 152 of the second sealing structure 15, thereby improving the sealing performance between the second sealing structure 15 and the mounting cavity 94.

Referring to fig. 3 to 4, in a state in which the cover 20 is provided on the body 10, the air passing hole 92 is higher than the lowest position of the first passage 141, and thus, the sidewall of the first sealing structure 14 forms a water blocking member. By skillfully utilizing the connection relationship between the first sealing structure 14 and the installation cavity 94 in a sliding fit manner, the first sealing structure 14 is arranged as a water blocking member, so that the whole structure is more compact on the basis of ensuring that water can be blocked from entering the sliding connection structure 90 through the air leakage channel 80.

Referring to fig. 1, a receiving space 16 is provided on the outer side of the machine body 10, the water receiving container 50 is disposed in the receiving space 16, the second sealing structure 15 is an elastic sealing ring, and the bottom of the second sealing structure 15 extends into the receiving space 16 and abuts against the water inlet 51 on the top of the water receiving container 50, so that the sealing communication between the water draining channel 71 and the water receiving container 50 is realized. The second sealing structure 15 is in sealing contact with the water inlet 51 of the water receiving container 50, so that the sealing connection of the two is realized, and meanwhile, the second sealing structure 15 can assist in fixing the water receiving container 50, so that the water receiving container 50 is fixed in the accommodating space 16. The water receiving container 50 is detachably connected through the second sealing structure 15, so that when more water is in the water receiving container 50, the water receiving container 50 can be directly taken down to pour out the water, and the water receiving container is convenient for a user to use.

Example 2

The overall structure of the heating type garbage disposer is mostly the same as that of the garbage disposer in embodiment 1, and the details of the structure are not repeated here. In this embodiment, the structure of the condensing assembly 40 in the waste disposer is further provided.

Referring to fig. 1, a condensing space 42 is provided in the condensing plate 41, and a cooling medium is provided in the condensing space 42, and is in contact with a non-condensing surface 413 of the condensing plate 41. By providing the cooling medium in the condensation space 42, the cooling medium sufficiently cools the condensation plate 41, further increasing the rate of condensed water vapor on the condensation surface 411, so that the condensed water can submerge the water outlet 721 of the water collecting member 72, and the flow of odor is blocked.

The cooling medium is a cooling liquid, and water or other cooling liquids can be selected as the specific choice. The condensing unit 40 further includes a power device 43 and a circulation channel, and the power device 43 may be a water pump for driving the cooling liquid to circulate in the condensing space 42 and the circulation channel, thereby further improving the cooling effect of the condensing plate 41. Specifically, the cover 20 is provided with the input pipe 24 and the return pipe 25, one end of the input pipe 24 communicates with the condensation space 42, so that the cooling liquid is input into the condensation space 42, and then flows on the non-condensation surface 413 of the condensation plate 41, the other end of the input pipe 24 communicates with one end of the return pipe 25, and the other end of the return pipe 25 communicates with the condensation space 42. A cooling liquid tank 100 and the power device 43 are communicated between the input pipe 24 and the output pipe. During cooling, under the driving of the power device 43, the cooling liquid in the cooling liquid box 100 sequentially flows through the input pipe 24, the non-condensing surface 413 of the condensing plate 41 in the condensing space 42 and the return pipe 25, and finally flows back into the cooling liquid box 100, so that the cooling liquid realizes circulating flow, and the condensing efficiency of the condensing plate 41 is improved.

Referring to fig. 1, the condensing plate 41 has a more specific structure: a partition 421 is disposed in the condensation space 42, and the partition 421 is configured to partition the condensation space 42 into a first space 422 for accommodating the condensate condensing plate 41 and a second space 423 for refluxing condensate in the first space 422, where the first space 422 is in communication with the second space 423. The first space 422 has a shape similar to the condensation surface 411, and is a concave groove structure gradually concave inward from the outer circumferential side thereof to the inner side, and has a highest height at the intermediate position, and a position where the first space 422 communicates with the second space 423 is located at the position. One end of the input pipe 24 communicates with the first space 422, the other end of the input pipe 24 communicates with one end of the return pipe 25, and the other end of the return pipe 25 communicates with the second space 423. During cooling, under the driving of the power device 43, the cooling liquid in the cooling liquid tank 100 flows into the first space 422 through the input pipe 24, and as the position where the first space 422 is communicated with the second space 423 is located at the highest position of the first space 422, the cooling liquid fills the first space 422, so that the cooling liquid and the non-condensing surface 413 of the condensing plate 41 perform sufficient heat exchange, and the condensing effect of the condensing plate 41 is improved; when the first space 422 is filled with the coolant, the coolant flows from the first space 422 into the second space 423, and then flows back to the coolant tank 100 through the return pipe 25.

Referring to fig. 1, the coolant tank 100 and the power unit 43 are located at the bottom of the machine body 10, and a first pipe 17 for communicating the coolant tank 100 with the input pipe 24 and a second pipe 18 for communicating the coolant tank 100 with the return pipe 25 are provided in the machine body 10, and when the cover 20 is covered on the machine body 10, the first pipe 17 is communicated with the input pipe 24, the second pipe 18 is communicated with the return pipe 25, and the coolant tank 100, the first pipe 17, the input pipe 24, the first space 422, the second space 423, the output pipe and the second pipe 18 form a flow path through which the coolant circulates.

Example 3

The overall structure of the heating type garbage disposer is mostly the same as that of the garbage disposer in embodiment 2, and the details of the structure are not repeated here. In the present embodiment, a structure different from that of the condensation module 40 in embodiment 2 is provided.

Referring to fig. 5, the input pipe 24 of the cover 20 is a spray pipe 26 for spraying the cooling liquid to the non-condensing surface 413 of the condensing plate 41, and when the cover 20 is covered on the body 10, one end of the spray pipe 26 is communicated with the first pipe 17, and the other end of the spray pipe 26 faces the condensing plate 41 to spray the cooling liquid to the non-condensing surface 413 of the condensing plate 41; one end of the return pipe 25 is connected to the bottom of the condensation space 42, and the other end of the return pipe 25 is connected to the second conduit 18. When cooling, under the drive of the power device 43, when the cooling liquid flows to the outlet of the spraying pipe 26, the cooling liquid is uniformly sprayed to the non-condensing surface 413 of the condensing plate 41, so that the cooling liquid can fully exchange heat with the non-condensing surface 413, and the condensing effect of the condensing plate 41 is improved. In addition, compared with the mode that the cooling liquid flows in the condensation space 42, the cooling liquid in the condensation space 42 can be cooled by spraying, so that the weight of the cover body 20 is reduced, the gravity center of the cover body 20 is lowered, and the stability of the garbage disposer during placement is ensured.

In the present embodiment, the coolant tank 100 is detachably connected to the bottom of the machine body 10 (fig. 5), but it is also possible to integrally form the coolant tank with the bottom of the machine body 10 (fig. 6), and the coolant tank may be specifically set according to needs.

As an alternative, referring to fig. 7-8, the coolant tank 100 may be disposed on a side of the tank or outside the machine body 10, and in use, the power device 43 may draw coolant from the tank to the spray pipe 26, and then spray the coolant uniformly to the non-condensing surface 413 of the condensing plate 41. Or referring to fig. 9, the cooling liquid box 100 is disposed above the condensation space 42, the bottom of the cooling liquid box 100 is provided with a spray hole 101, the spray hole 101 is the spray pipe 26, and when in use, under the action of gravity, the cooling liquid in the cooling liquid box 100 is sprayed to the non-condensation surface 413 of the condensation plate 41 through the spray hole 101.

As another alternative, referring to fig. 10, the condensing space 42 is a cooling liquid tank 100 for storing cooling liquid, and the cooling liquid is placed in the non-condensing space 42 to directly cool the condensing plate 41, so that the power device 43 and the circulation channel are reduced, the cost is saved, and the whole structure is simpler and more compact.

Example 4

The overall structure of the heating type garbage disposer is mostly the same as that of the garbage disposer in embodiment 1, and the details of the structure are not repeated here. In the present embodiment, a structure different from that of the condensation module 40 in embodiment 2 is provided.

Referring to fig. 11, the cooling medium is air, the condensing assembly 40 further includes an air blowing device 44, and the air blowing device 44 is specifically selected as a fan, and the air blowing device 44 is used for driving the external air to flow to the non-condensing surface 413, so that the heat exchange efficiency between the non-condensing surface 413 and the space is improved, and the condensing effect of the condensing plate 41 is improved. Specifically, the air blowing device 44 is provided above the condensing plate 41 so as to blow air positively onto the condensing plate 41. Alternatively, referring to fig. 12, an air blowing device 44 is provided at a side of the condensing plate 41 to blow air side-on the condensing plate 41.

To increase the heat exchange efficiency of the air and the non-condensing surface 413, referring to fig. 13, the condensing plate 41 may be provided in a double-layer or multi-layer structure, which increases the heat exchange area, increases the condensing rate, and ensures that enough condensed water can quickly flow to the water collecting member 72 to block the flow of the odor through the water inlet channel 70.

It is to be understood that the above examples of the present utility model are provided by way of illustration only and not by way of limitation of the embodiments of the present utility model. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (12)

1. A heated waste disposer, comprising:

the garbage disposal device comprises a machine body and a cover body, wherein the cover body is detachably arranged on the machine body, and a garbage disposal cavity for disposing garbage is formed between the machine body and the cover body;

a sliding connection structure arranged in the machine body;

the elastic piece, connect to the first seal structure of one end of the elastic piece and connect to the second seal structure of another end of the elastic piece, the said first seal structure is in sliding fit with sliding connection structure and its top supports the press fit with the bottom of the cover under the function of the elastic piece, there are first channels in the said first seal structure, there are second channels in the said second seal structure, the said elastic piece has hollow channels which communicate the said first channel and second channel;

the heating component is arranged in the garbage treatment cavity and is used for evaporating water in the garbage to form water vapor;

the condensing assembly is used for condensing and liquefying the water vapor into condensed water and is provided with a guide structure for guiding the condensed water to the first channel;

and the water receiving container is communicated with the second channel.

2. A heated waste disposer as claimed in claim 1, wherein: the condensing assembly comprises a condensing plate, wherein the surface, close to the heating assembly, of the condensing plate serves as a condensing surface for condensing and liquefying the water vapor, and a guiding surface for guiding condensed water to the first channel under the action of gravity is formed by gradually and inwards concave the condensing surface from the outer periphery side of the condensing surface, and the guiding surface serves as the guiding structure.

3. A heated waste disposer as claimed in claim 1, wherein: the device also comprises a water collecting piece for collecting the condensed water, and a water outlet communicated with the first channel is arranged at the bottom of the water collecting piece.

4. A heated waste disposer as claimed in claim 3, wherein: the water collecting piece is arranged at the bottom of the cover body, and when the cover body is covered on the machine body, the bottom of the water collecting piece is in abutting fit with the end part, far away from the elastic piece, of the first sealing structure.

5. A heated waste disposer as claimed in claim 1, wherein: the garbage treatment cavity, the first sealing structure, the elastic piece, the second sealing structure and the water receiving container are communicated to form a sealing space, and the condensing assembly condenses and liquefies the water vapor so as to control the pressure intensity in the sealing space to be in a range of 0 kPa-34 kPa.

6. A heated waste disposer as claimed in claim 5, wherein: the ratio of the condensation water quantity in unit time of the condensation component to the evaporation quantity in unit time of the heating component is 0.3-1, so that the pressure is controlled.

7. A heated waste disposer as claimed in claim 5, wherein: the sliding structure is internally provided with an inner wall so as to divide the sliding structure into a filter cavity close to the outer side and a hollow installation cavity, filter materials are arranged in the filter cavity, the upper end and the lower end of the installation cavity are communicated, and an air leakage channel is arranged between the filter cavity and the sealing space.

8. The heated waste disposer of claim 7, wherein: the end part of the air leakage channel, which is close to the elastic piece, is provided with a water blocking piece, and a gap exists between the water blocking piece and the air leakage channel.

9. A heated waste disposer as claimed in claim 8, wherein: the first sealing structure and the second sealing structure are in sealing fit with the mounting cavity, the elastic piece is provided with a communication channel which is communicated with the hollow channel and the mounting cavity, the inner wall is provided with an air passing hole which is communicated with the filter cavity and the mounting cavity, and the communication channel and the air passing hole are used as air leakage channels;

when the cover body is covered on the machine body, the air passing hole is higher than the lowest position of the first channel, and the first sealing structure is used as a water retaining member.

10. A heated waste disposer as claimed in claim 1, wherein: the sliding connection structure comprises a box body and a box cover, a through hole is formed in the bottom of the box body, a connecting lug extending outwards is arranged at the top of the second sealing structure, the connecting lug is arranged at the edge of the top of the through hole, an inner wall extending towards the bottom of the box body is arranged on the cover body, the first sealing structure is in sliding fit with the inner wall, and the bottom of the inner wall is in abutting fit with the connecting lug;

the inner wall is equipped with the block, the tip that the elastic component kept away from first seal structure is located on the block.

11. A heated waste disposer as claimed in claim 1, wherein: and a limiting part is arranged in the machine body, and when the cover body is covered on the machine body, the first sealing structure is abutted against the limiting part under the action of the elastic part.

12. A heated waste disposer as claimed in claim 1, wherein: the machine body is provided with a containing space, the water receiving container is arranged in the containing space, the second sealing structure is an elastic sealing ring, and the bottom of the second sealing structure stretches into the containing space and abuts against the water receiving container.