CN112826328A - Automatic cleaning method of food processing machine - Google Patents

Abstract

The invention discloses an automatic cleaning method of a food processor, wherein the food processor comprises a crushing cavity and a water supply component for supplying water to the crushing cavity, the crushing cavity is provided with a crushing component, a heating component and a pulp discharging component, the crushing cavity is cleaned at least by a rinsing stage and a steaming stage after the preparation of the food processor is finished, and the steaming stage is positioned after the rinsing stage; rinsing stage: the water supply part injects water into the crushing cavity, the crushing part stirs the water to clean the crushing cavity, and the slurry discharge assembly discharges residual water in the crushing cavity; and (3) steaming and washing stage: the water supply part is to smashing the chamber water injection, and control heating element produces steam to the water heating who smashes the chamber, steam fumigation smashes the chamber wall, and crushing part stirring water washs smashing the chamber, and the thick liquid subassembly of row will smash the surplus water discharge of intracavity.

Description

Automatic cleaning method of food processing machine

Technical Field

The invention relates to the field of food processing machines, in particular to an automatic cleaning method for food processing.

Background

A food processor is a household appliance for heating and crushing materials, and comprises a soybean milk machine and a wall breaking machine.

After the soybean milk machine makes soybean milk, the inner wall of the cup body is easy to be stained with granular residues. The existing automatic cleaning mode is to add water to the inner wall of the cup body, and then a motor drives the water to stir and clean.

However, the cleaning method can only clean large granular residues, and the cleaning effect is poor for individual small granular residues, so that the small granular residues are remained on the inner wall of the cup body after cleaning.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide an automatic cleaning method of a food processor, which can discharge large-particle residues in time and soften small-particle residues so as to improve the cleaning effect of the small-particle residues.

The technical purpose of the invention is realized by the following technical scheme: a method of automatically cleaning a food processor, the food processor including a grinding chamber and a water supply assembly for supplying water to the grinding chamber, the grinding chamber having a grinding assembly, a heating assembly and a slurry discharge assembly, the method comprising: after the food processor is prepared, cleaning the crushing cavity at least comprises a rinsing stage and a steaming stage, wherein the steaming stage is positioned after the rinsing stage;

rinsing stage: the water supply part injects water into the crushing cavity, the crushing part stirs the water to clean the crushing cavity, and the slurry discharge assembly discharges residual water in the crushing cavity;

and (3) steaming and washing stage: the water supply part is to smashing the chamber water injection, and control heating element produces steam to the water heating who smashes the chamber, steam fumigation smashes the chamber wall, and crushing part stirring water washs smashing the chamber, and the thick liquid subassembly of row will smash the surplus water discharge of intracavity.

Preferably, the method further comprises the following steps: and in the drying stage, the heating assembly heats, dries and crushes the cavity.

Preferably, the crushing component comprises a crushing blade arranged in the crushing cavity, and the water supply component injects water with the volume of V1 in the rinsing stage, and the injected water passes through the top end of the crushing blade.

Preferably, in the rinsing stage, after the crushing member stirs water to clean the crushing cavity, the slurry discharge assembly discharges residual water in the crushing cavity while the crushing member continues to rotate.

Preferably, the rated power of the crushing member is P0, and in the rinsing stage, before the crushing cavity discharges residual water, the crushing member stirs the water with the power of P1 to clean the crushing cavity, and P1= P0/5.

Preferably, in the steaming and washing stage, the water supply part is filled with water for a plurality of times, water of V2 is filled in the starting stage for vaporization fumigation, after the pulverization chamber is vaporized and fumigated, the water supply part is filled with water of V3 for fumigation, and V2 is less than V3.

Preferably, in the steaming and washing stage, water injected with V3 is mixed with water in the crushing cavity, and the temperature of the mixed water is more than 70 ℃.

Preferably, in the steaming and washing stage, after the water V3 is fed, the crushing members rotate with different powers to stir the liquid in the crushing cavity.

Preferably, the bottom of the crushing cavity is provided with a first temperature sensor, the detection temperature is K2, the temperature of the bottom of the crushing cavity is controlled to be maintained at T2 in the drying stage, and the heating is stopped when the temperature of T reaches T2-8 ℃ for the first time; when K2 is less than T2-8 ℃ to delta T, the heating component recovers heating; heating was then stopped when K2> T2, Δ T =2 ℃.

Preferably, a second temperature sensor for detecting steam is arranged on the inner side wall of the crushing cavity, the detected temperature is K1, the temperature T1 is preset in the steaming and washing stage, and when K1 is larger than T1, the crushing component is controlled to rotate.

In summary, compared with the prior art, the beneficial effects of the invention are as follows:

1. the residual water with large-particle residues is discharged through the slurry discharging assembly, so that the large-particle residues in the residual water are prevented from being adhered to the small-particle residues again, and the interference of the large-particle residues on subsequent cleaning is reduced; the small-particle residues are softened by steaming, so that the small-particle residues are easier to clean, the small-particle residues remained in the inner cavity of the crushing cup after cleaning are reduced, and the automatic cleaning effect is further improved;

2. the essence of the cleaning in the rinsing stage is that water is stirred by the crushing blades for cleaning, the larger the contact surface between the blades and the water is, the better the stirring cleaning effect is, and when the injected water passes through the crushing blades, the best stirring cleaning effect is;

3. the crushing part stirs the residual water, so that not only can the crushing cavity be further cleaned, but also large-particle residues cleaned in the residual water can be prevented from being re-precipitated on the bottom wall of the crushing cavity, and the discharge of the large-particle residues is facilitated;

4. the total water amount required in the steaming and washing stage is V2+ V3, but the water amount required for heating to be changed into water steaming and washing is not more than V2; compared with the method that all water is injected at one time, the water is injected twice, so that the time for heating the water to generate steaming and washing can be shortened, and the water of V3 is injected during the subsequent washing; in addition, when the water temperature is above 70 ℃, the water solubility is good, some oily substances can be effectively removed, and meanwhile, the high-temperature water has good bactericidal property, so that the cleaning effect is improved;

5. the water flow which is cleaned twice by adopting different powers produces different effects, and the parts which can not be cleaned twice are not positioned at the same side, so that the cleaning effect is improved, and the cleaning dead angle is avoided. In other embodiments, the milling unit may also agitate the water with constant power to clean the milling chamber during the steam washing stage;

6. through direct detection air temperature, can in time discern the time of producing steam, at this moment, the tiny particle residue begins to be softened, and control crushing unit stirs water, in time washs the tiny particle residue.

Drawings

Fig. 1 is a schematic view of a food processor.

Reference numerals: 1. a grinding chamber; 11. a grinding cup; 12. a cup cover; 2. a water supply unit; 21. a water tank; 3. a heating assembly; 4. a slurry discharge assembly; 5. a pulverizing member; 51. a motor; 52. and (4) crushing blades.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, which is a schematic structural view of a food processor of the present invention, the food processor includes a grinding chamber 1, a water supply unit 2 for supplying water to the grinding chamber 1, and the grinding chamber 1 is provided with a grinding unit 5, a heating assembly 3 and a slurry discharge assembly 4. The crushing cavity 1 is formed by matching a crushing cup 11 and a cup cover 12; the crushing component 5 comprises a crushing blade 52 and a motor 51 which are positioned in the crushing cup 11, wherein the crushing blade 52 is arranged on a main shaft of the motor 51; the water supply component 2 is a water tank 21 communicated with the crushing cavity 1 through a pipeline; the heating component 3 is a heating pipe arranged on the crushing cup 11; the slurry discharge assembly 4 is a slurry discharge pipe of the communicated crushing cup 11.

The automatic cleaning method comprises an automatic cleaning method which comprises a rinsing stage and a steaming stage which are sequentially carried out.

Rinsing stage: the water is injected into the crushing cavity 1 by the supply parts, the crushing part 5 stirs water to clean the crushing cavity 1, and the residual water in the crushing cavity 1 is discharged by the slurry discharge assembly 4.

And (3) steaming and washing stage: water supply unit 2 is to smashing 1 water injection in chamber, and control heating element 3 produces steam to the water heating who smashes chamber 1, the stifling chamber 1 chamber wall that smashes of steam, crushing unit 5 stirring water washs smashing chamber 1, arranges thick liquid subassembly 4 and will smash the surplus water discharge in the chamber 1.

The residue particles are large and small, with large particles generally covering the small particles. At the rinsing stage, crushing member 5 stirs crushing chamber 1 slope, can clear away the large granule residue of crushing chamber 1 inner wall, then discharges with the residual water that will have the large granule residue through arranging thick liquid subassembly 4 to avoid the residue in the residual water to disturb follow-up washing again. Follow-up steaming and washing stage need heat the steam production, through the residue investigation with big granule in the surplus water, can avoid water evaporation to lead to the large granule residue to glue again and smash 1 inner wall in chamber. Before entering the steaming and washing stage, the rinsing stage is repeated at least twice to ensure that large-particle residues are cleaned.

At the steam-washing stage, clean water is reinjected into to crushing chamber 1 to water supply unit 2, and control heating element 3 produces steam to the water heating of crushing chamber 1, and steam temperature can exceed 100 degrees, fumigates the residue of tiny granule through steam for the residue of tiny granule softens, weakens at the adhesive capacity of crushing chamber 1 inner wall. Then, the crushing chamber 1 is cleaned by agitating water by the crushing member 5 so that most of the small particle residue can be cleaned. Finally, residual water in the crushing cavity 1 is discharged through the slurry discharge assembly 4.

Soften the tiny particle residue through steaming for the tiny particle residue is washd more easily, smashes the remaining tiny particle residue of 11 inner chambers of cup after reducing the washing, and then promotes the self-cleaning effect.

In this embodiment, the automatic cleaning method further includes a drying stage, the drying stage is located after the steaming and washing stage, and in the drying stage, the heating assembly 3 heats, dries, and crushes the cavity 1. Make the residual water of evaporating washing stage not have through drying, help guaranteeing that there is not residual water to remain after the washing, reduce bacterial growing. In addition, in the drying stage, the water quantity in the crushing cavity 1 is smaller than that in the steaming and washing stage, so that the temperature is difficult to reduce through water evaporation, and the temperature of the inner wall of the crushing cavity 1 is higher than that in the steaming and washing stage and the rinsing stage. That is, when the heating assembly 3 is heated at the same power in the steaming and washing stage, the inner wall of the crushing cavity 1 can be raised to a higher temperature, so as to achieve the purpose of high-temperature sterilization.

Specifically, in the drying stage, the pulp discharging assembly 4 is in an open state, and the heating assembly 3 is controlled to heat the crushing cup 11 at the full power of 1000W. During the in-process bowl cover 12 of stoving can the condensation water droplet constantly drip to smashing cup 11, keep arranging thick liquid subassembly 4 and open and discharge from smashing chamber 1 after making the water droplet gathering of drippage, it is poor to avoid smashing 11 bottom waters accumulation excess drying effect. During drying, the crushing cup 11 is in a dry-burning state, and the excessive power can cause great drying temperature fluctuation and damage to the coating. When the power is too low, the temperature of the cup body rises slowly, the drying time is long, the drying power of 1000W can be simultaneously considered, and the effect is good.

In other embodiments, the automatic cleaning mode is only the rinsing phase and the subsequent steaming phase.

In this embodiment, the water supply unit 2 supplies water of V1 in the rinsing stage, and the supplied water passes through the crushing blades 52. The cleaning in the rinsing stage is performed by agitating water with the crushing blades 52, and the larger the contact surface of the blades with water, the better the agitating cleaning effect. The agitation washing effect is best when the injected water passes over the pulverizing blades 52.

Specifically, in the rinsing stage, crushing member 5 stirs water and smashes chamber 1 back in order to wash, arrange thick liquid subassembly 4 and discharge again and smash the interior surplus water of chamber 1, crushing member 5 continues to rotate simultaneously, when arranging thick liquid subassembly 4 row thick liquid promptly, crushing member 5 stirs the surplus water, not only can further wash crushing chamber 1, can deposit crushing chamber 1 diapire again to the large granule residue of avoiding wasing in the surplus water moreover, helps the discharge of large granule residue.

In other embodiments, after the crushing member 5 stirs water to clean the crushing chamber 1 in the crushing stage, the crushing member 5 stops rotating, and the slurry discharge assembly 4 discharges the residual water.

In this embodiment, the power limit of the crushing member 5 is P0, and in the rinsing stage, before the crushing chamber 1 discharges the residual water, the crushing member 5 stirs the water with the power P1 to clean the crushing chamber 1, and P1= P0/5. The power of the crushing member 5 is the power of the motor 51. By limiting the power of the comminution member 5 during the rinsing phase to 1/5, the liquid in the comminution chamber 1 is prevented from splashing, thereby reducing the possibility of the liquid overflowing the comminution chamber 1.

In the steaming and washing stage, the water supply part 2 is injected with water for a plurality of times, water of V2 is injected for steam smoking in the initial stage, after the crushing cavity 1 is steamed by steam, water of V3 is injected for steam smoking by the water supply part 2 for a plurality of times, and V2 is less than V3. The total amount of water required for steaming and washing is more than V2, and the time for heating to generate steam can be reduced by dividing the water into a plurality of small parts. Meanwhile, the water supply part 2 injects water for many times, so that the water generated at each time end is evaporated and washed more uniformly and has longer duration, and the steaming and smoking effects and the small-particle residue softening effects are improved.

In the steaming and washing stage, water injected with V3 is mixed with water in the crushing cavity 1, and the water temperature after mixing is higher than 70 ℃, namely (V3 t1+ V2 100)/(V3 + V2) >70, wherein t1 is the water temperature of the water injected with V3.

The total amount of water required for the steam wash stage is V2+ V3, but the amount of water actually required to be heated to steam wash water is no more than V2. Compared with the method of injecting all water at one time, the time for heating the water to generate steaming washing can be shortened by injecting water twice, and water of V3 is injected in the subsequent washing. In addition, when the water temperature is above 70 ℃, the water solubility is good, some oily substances can be effectively removed, and meanwhile, the high-temperature water has good bactericidal property, so that the cleaning effect is improved.

In the steaming and washing stage, after water V3 enters, the crushing part 5 rotates with different powers to stir the liquid in the crushing cavity 1, namely, the crushing part 5 stirs the liquid in the crushing cavity 1 for a plurality of times, and the powers are different at least for two times. Specifically, the motor 51 in the pulverization apparatus 5 is operated for 30s at 11000 revolutions, and then the pulverization chamber 1 is cleaned by being rotated for 30s at 13000 revolutions.

The inner wall of the crushing cavity 1 is not smooth, the water flow is not stable after the motor 51 rotates at a high speed, and a small part of the inner wall of the crushing cavity 1 cannot be cleaned. The water flow which is cleaned twice by adopting different powers produces different effects, and the parts which can not be cleaned twice are not positioned at the same side, so that the cleaning effect is improved, and the cleaning dead angle is avoided. In other embodiments, the milling unit 5 can also agitate the water with constant power during the steaming phase to clean the milling chamber 1.

In this embodiment, the bottom of the pulverization chamber 1 is provided with a first temperature sensor, and the detected temperature is K2. In the drying stage, the temperature of the bottom of the crushing cavity 1 is controlled to be maintained at T2, and when T reaches T2-8 ℃ for the first time, the heating is stopped; when K2 is lower than T2-8 ℃ to delta T, the heating component 3 is heated again; heating was then stopped when K2> T2, Δ T =2 ℃. Where T2=90 ℃. In the drying phase, the higher the maintaining temperature setting, the faster the speed of water evaporation in the grinding cup 11, and the greater the drying efficiency, but too high maintaining temperature will result in high overall temperature of the grinding cup 11, which will reduce the coating life, while too high temperature at the edge of the grinding cup 11 presents the risk of scalding hands, for which reason T2=90 ℃. Because the temperature of the grinding cup 11 is lower after the cleaning is finished, the time for heating the grinding cup 11 to T2 ℃ is longer, the thermal inertia is large after the heating is stopped, the highest temperature of the grinding cup 11 after the heating is stopped is far larger than the maintaining temperature T2, and in order to solve the problem, the setting of the first heating control threshold value after the heating is smaller than T2, namely the heating is stopped when the T reaches T2-8 ℃ for the first time. When the temperature of the grinding cup 11 approaches T2 deg.C, the heating control threshold is adjusted to T2. Meanwhile, in order to avoid frequent switching of the heating assembly 3, a temperature difference delta T =2 ℃ needs to exist between the heating starting temperature and the heating closing temperature.

In this embodiment, the crushing chamber 1 inside wall is equipped with the second temperature sensor that is used for detecting steam, and the temperature that detects is K1. In the steaming and washing stage, the temperature T1 is preset, and when K1 is greater than T1, the rotation of the crushing component 5 is controlled.

After the steam is generated, the air temperature in the crushing cavity 1 breaks through the preset temperature T1, the time for generating the steam can be identified in time by directly detecting the air temperature, at the moment, the small-particle residues begin to be softened, the crushing component 5 is controlled to stir water, and the small-particle residues are cleaned in time.

The above description is intended to be illustrative of the present invention and not to limit the scope of the invention, which is defined by the claims appended hereto.

Claims (10)

1. A method of automatically cleaning a food processor, the food processor including a grinding chamber and a water supply assembly for supplying water to the grinding chamber, the grinding chamber having a grinding assembly, a heating assembly and a slurry discharge assembly, the method comprising: after the food processor is prepared, cleaning the crushing cavity at least comprises a rinsing stage and a steaming stage, wherein the steaming stage is positioned after the rinsing stage;

rinsing stage: the water supply part injects water into the crushing cavity, the crushing part stirs the water to clean the crushing cavity, and the slurry discharge assembly discharges residual water in the crushing cavity;

and (3) steaming and washing stage: the water supply part is to smashing the chamber water injection, and control heating element produces steam to the water heating who smashes the chamber, steam fumigation smashes the chamber wall, and crushing part stirring water washs smashing the chamber, and the thick liquid subassembly of row will smash the surplus water discharge of intracavity.

2. The method of claim 1, wherein the step of automatically cleaning the food processor comprises: further comprising: and in the drying stage, the heating assembly heats, dries and crushes the cavity.

3. A method of automatic cleaning of a food processor as claimed in claim 1 or 2, characterized in that: the crushing component comprises a crushing blade arranged in the crushing cavity, the water supply component injects water with the volume of V1 in the rinsing stage, and the injected water passes through the top end of the crushing blade.

4. The method for automatically washing and drying a food processor as claimed in claim 1 or 2, wherein: in the rinsing stage, after the crushing component stirs water to clean the crushing cavity, the slurry discharge assembly discharges residual water in the crushing cavity, and meanwhile, the crushing component continues to rotate.

5. The method for automatically washing and drying a food processor as claimed in claim 1 or 2, wherein: the rated power of the crushing component is P0, and in the rinsing stage, before the residual water is discharged from the crushing cavity, the crushing component stirs the water with the power of P1 to clean the crushing cavity, wherein P1= P0/5.

6. The method for automatically washing and drying a food processor as claimed in claim 1 or 2, wherein: in the steaming and washing stage, water supply part is filled with water for multiple times, water of V2 is filled in the initial stage for vaporization fumigation, after the pulverization chamber is vaporized and fumigated, water of V3 is filled in the pulverization chamber for fumigation, and V2 is less than V3.

7. The method of claim 6, wherein the step of automatically cleaning and drying the food processor comprises: in the steaming and washing stage, water injected with V3 is mixed with water in the crushing cavity, and the temperature of the mixed water is more than 70 ℃.

8. The method of claim 6, wherein the step of automatically cleaning the food processor comprises: in the steaming and washing stage, after water V3 is fed, the crushing members rotate with different powers to stir the liquid in the crushing cavity.

9. The method of claim 2, wherein the step of automatically cleaning the food processor comprises: a first temperature sensor is arranged at the bottom of the crushing cavity, the detection temperature is K2, the temperature at the bottom of the crushing cavity is controlled to be maintained at T2 in the drying stage, and the heating is stopped when the temperature T reaches T2-8 ℃ for the first time; when K2 is less than T2-8 ℃ to delta T, the heating component recovers heating; heating was then stopped when K2> T2, Δ T =2 ℃.

10. A method of automatic cleaning of a food processor as claimed in claim 1 or 2, characterized in that: the crushing intracavity lateral wall is equipped with the second temperature sensor that is used for detecting steam, and the temperature that detects is K1, and in the steaming and washing stage, preset temperature T1, when K1 is greater than T1, control crushing part rotates.

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