CN109170507A

CN109170507A - food safety machine

Info

Publication number: CN109170507A
Application number: CN201810911917.5A
Authority: CN
Inventors: 孙毅; 张士伟
Original assignee: Ten Food Safety Purification Technology (jiangsu) Co Ltd
Current assignee: Ten Food Safety Purification Technology (jiangsu) Co Ltd
Priority date: 2018-08-10
Filing date: 2018-08-10
Publication date: 2019-01-11

Abstract

The invention discloses a kind of food safety machines.It includes safe machine ontology, covers upper cover, electrode module, water level detecting component and the electric-controlled plate being located on the safe machine ontology, wherein: the upper cover lid is closed in one end of the safe machine ontology, accommodating chamber is formed between the upper cover and the safe machine ontology, and electrode module is set in the accommodating chamber；The water level detecting component is set in the accommodating chamber, and the water level detecting component is electrically connected with the electric-controlled plate；The electric-controlled plate according to the water level detecting component detection to information determine meet electrolytic condition when, control the electrode module and carry out electrolysis work；Achieve the effect that receive user triggers the operation that food safety machine works manually.

Description

Food safety machine

Technical Field

The invention relates to the field of food purification devices, in particular to a food safety machine.

Background

A food safety machine is an apparatus for purifying food products such as vegetables, fruits, meats. The food safety machine generally comprises an electrode module and a purification tank body arranged on one side of the electrode module, wherein water in the purification tank body can enter the electrode module, the electrode of the electrode module is used for electrolyzing the water to generate electrolyzed water, and the electrolyzed water is contacted with food in the purification tank, so that substances such as pesticides, hormones and viruses on the food are dissolved in the electrolyzed water, and then the purification operation of the food is realized.

At present, a user needs to manually trigger the food safety machine to work, and the operation is complex.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the problems in the prior art, a food safety machine is provided. Food safety machine includes that safety machine body, lid are established upper cover, electrode module, water level detection subassembly and automatically controlled board on the safety machine body, wherein:

the upper cover covers one end of the safety machine body, an accommodating cavity is formed between the upper cover and the safety machine body, and an electrode module is arranged in the accommodating cavity;

the water level detection assembly is arranged in the accommodating cavity and is electrically connected with the electric control board;

and when the electric control board determines that the electrolysis condition is met according to the information detected by the water level detection assembly, the electrode module is controlled to carry out electrolysis work.

Optionally, the water level detection assembly is a liquid level detector, or the water level detection assembly includes two sensing electrodes and a resistance detection device for detecting the resistance between the two sensing electrodes.

Optionally, when the electronic control board determines that the electrolysis condition is met according to the information detected by the water level detection assembly, the electronic control board controls the electrode module to perform electrolysis work, including:

the electric control board controls the electrode module to carry out electrolysis work when the liquid level value detected by the liquid level detector reaches a preset liquid level;

or,

and the electric control board controls the electrode module to carry out electrolysis work when the resistance value detected by the resistance value detection device is lower than a preset resistance value.

Optionally, the electronic control board further controls the electrode module to stop the electrolytic work when the liquid level value detected by the liquid level detector is lower than a predetermined liquid level; or,

the electric control board also controls the solution module to stop electrolysis when the resistance value detected by the resistance value detection device is higher than the preset resistance value.

Optionally, the liquid level detector is disposed on an end surface of the safety machine body facing the upper cover.

Optionally, the safety device body is located on the end face in the accommodating cavity, a power switch is further arranged on the end face, wherein:

if the electrode module does not perform electrolysis work and the power switch is triggered, controlling the electrode module to perform electrolysis work;

and if the electrode module detects that the power switch is triggered in the process of carrying out electrolysis work, controlling the electrode module to stop the electrolysis work.

Optionally, the plurality of electrode plates are sequentially stacked, and the polarities of every two adjacent electrode plates are opposite.

Optionally, the electrode plate is arranged in parallel to the end face of the safety machine body.

Optionally, a plurality of mounting holes are formed in the circumferential surface of the electrode plate, and fasteners are inserted into the mounting holes to fix the electrode plate on the end surface of the safety engine body.

Optionally, the plate electrode is provided with a through hole, the through holes penetrate through to form a positioning hole, and the upper cover is convexly provided with a positioning column corresponding to the positioning hole.

The invention has the beneficial effects that: the invention provides a food safety machine, which comprises a safety machine body, an upper cover covered on the safety machine body, an electrode module, a water level detection assembly and an electric control plate, wherein: the upper cover covers one end of the safety machine body, an accommodating cavity is formed between the upper cover and the safety machine body, and an electrode module is arranged in the accommodating cavity; the water level detection assembly is arranged in the accommodating cavity and is electrically connected with the electric control board; the electric control board controls the electrode module to carry out electrolysis work when the electric control board determines that the electrolysis condition is met according to the information detected by the water level detection assembly; the problem of the user manually trigger the food safety machine to carry out work complex operation in the prior art is solved, and the effect of receiving the operation that the user manually triggers the food safety machine to carry out work is achieved.

Drawings

The invention is further illustrated by the following figures and examples.

FIG. 1 is a perspective view of the portable food safety machine of the present invention;

FIG. 2 is an exploded view of the portable food safety machine of FIG. 1;

FIG. 3 is a schematic view of the structure of the safety device body of the portable food safety device shown in FIG. 2;

FIG. 4 is a schematic view of the construction of the bottom cover of the portable food safety machine of FIG. 2;

FIG. 5 is another exploded view of the portable food safety machine of FIG. 1;

FIG. 6 is an enlarged view of a portion of the portable food safety machine of FIG. 5 at A;

FIG. 7 is a schematic view of the portable food safety machine of FIG. 6 in an installed state;

FIG. 8 is another schematic view of the portable food safety machine of FIG. 6 in an installed state;

FIG. 9 is yet another schematic view of the portable food safety machine of FIG. 6 in an installed state;

FIG. 10 is a cross-sectional view of the portable food safety machine of FIG. 1;

fig. 11 is a partially enlarged view of the portable food safety machine shown in fig. 10.

In the figure: 10. the safety machine body comprises a safety machine body, 11, a support member, 111, a peripheral wall, 112, a mounting groove, 113, a baffle plate, 114, a fixing groove, 115, a protrusion, 116, a first positioning hole, 117, a mounting hole, 118, a fixing column, 119, an injection hole, 12, a power supply module, 121, a battery, 13, an electrode module, 131, an electrode plate, 1311, a first electrode plate, 1312, a second electrode plate, 1313, a first electrode hole, 1314, a second electrode hole, 1315, a first through hole, 1316, a second positioning hole, 132, an insulating gasket, 1321, a second through hole, 1322, a guide hole, 133, a first electrode column, 134, a second electrode column, 135, a fastening hole, 14, an electronic control plate, 141, a fixing hole, 142, a through hole, 15, a power switch, 16, a buckle, 161, a first clamping strip, 162, a second clamping strip, 17, a limiting part, 18, a clamping groove, 181, an opening end, 20, a bottom cover, 21 and a first positioning column, 22. the mounting column 30, the upper cover 31, the through hole 32, the second positioning column 321, the charging port 322, the first charging electrode 323, the second charging electrode 324, the insulating sheet 325, the air inlet 33, the clamping block 34 and the water leakage hole.

Detailed Description

The present invention will now be described in detail with reference to the accompanying drawings. This figure is a simplified schematic diagram, and merely illustrates the basic structure of the present invention in a schematic manner, and therefore it shows only the constitution related to the present invention.

Referring to fig. 1 and 2, the present invention provides a portable food safety machine, which includes a safety machine body 10, a water level detection assembly 19, a bottom cover 20 and an upper cover 30 respectively covering both sides of the safety machine body 10.

Referring to fig. 1, 2 and 6, the safety device body 10 includes a supporting member 11, and a power module 12 and an electrode module 13 disposed on two sides of the supporting member 11, wherein the electrode module 13 is electrically connected to the power module 12.

The supporting member 11 is a plate-shaped structure, and in the present embodiment, an end surface of the supporting member 11 where the power module 12 is disposed is a first surface (not shown), an end surface of the supporting member 11 where the electrode module 13 is disposed is a second surface (not shown), and the bottom cover 20 covers the first surface of the supporting member 11, so that a sealed cavity (not shown) is formed between the bottom cover 20 and the supporting member 11. The upper cover 30 covers the second surface of the support 11, so that a receiving cavity (not shown) is formed between the upper cover 30 and the support 11, and it can be understood that the portable food safety machine formed by the support 11, the bottom cover 20 and the upper cover 30 can be in a rectangular shape, a spherical shape or an ellipsoidal shape, and in the present invention, the support 11 is in a disc shape, and the bottom cover 20 and the upper cover 30 are both in a semi-elliptical shell shape, so that the formed portable food safety machine is in an ellipsoidal shape, and is convenient to carry.

In addition, the water level detection assembly 19 is disposed in the accommodating cavity, and the water level detection assembly 19 is electrically connected with an electric control board (not shown in the figure); the electric control board controls the electrode module 13 to perform electrolysis when the electrolysis condition is satisfied according to the information detected by the water level detection assembly 19. The operation that the user manually triggers the food safety machine to carry out purification operation is saved.

Referring to fig. 2, a peripheral wall 111 is convexly disposed around the first surface of the supporting member 11, a mounting groove 112 is formed by the supporting member 11 and the peripheral wall 111, two opposite baffles 113 are disposed in the mounting groove 112, and a fixing groove 114 is formed in a space between the two baffles 113. In the present embodiment, the baffle 113 is a battery holder, and the plurality of batteries 121 are connected in series and electrically connected to the battery holders at both ends.

Referring to fig. 4 and 5, a protrusion 115 is convexly disposed in the middle of the supporting member 11, a first positioning hole 116 is disposed in the middle of the protrusion 115, a plurality of mounting holes 117 are disposed around the supporting member 11, a first positioning post 21 corresponding to the first positioning hole 116 is convexly disposed in the middle of the bottom cover 20, a plurality of mounting posts 22 corresponding to the plurality of mounting holes 117 are convexly disposed around the bottom cover 20, when the bottom cover 20 covers the supporting member 11, the first positioning post 21 can be inserted into the first positioning hole 116, and the mounting posts 22 can be inserted into the corresponding mounting holes 117.

In addition, an electric control board 14 is further disposed above the supporting member 11, the electric control board 14 is electrically connected to the power module 12, and the electric control board 14 controls the working time of the power module 12 and the stability of the output current of the power module 12.

The peripheral surface of the electric control board 14 is provided with a plurality of fixing holes 141, the supporting member 11 is convexly provided with a plurality of fixing posts 118 corresponding to the plurality of fixing holes 141, in this embodiment, the number of the fixing posts 118 is four, the number of the fixing holes 141 is also four, the four fixing posts 118 are uniformly arranged around the power module 12, when the electric control board 14 is placed on the supporting member 11, each fixing post 118 is inserted into the corresponding fixing hole 141, and meanwhile, the electric control board 14 can also fix the power module 12.

The electronic control board 14 is further provided with a through hole 142 corresponding to the first positioning hole 116, so that the first positioning column 21 can pass through the through hole 142 when the bottom cover 20 is covered on the supporting member 11.

The bottom cover 20 is hermetically mounted on the support 11, and it is understood that the sealing manner between the bottom cover 20 and the support 11 may be by a bolt connection or by sleeving a sealing sleeve on the outside of the bottom cover 20 and the support 11, in this embodiment, the support 11 is provided with at least two glue injection holes 119 communicating with the sealing cavity, when mounting, the electronic control board 14 is placed on the surface of the power module 12, then the bottom cover 20 is covered on the support 11, one end surface of the support 11, on which the electrode module 13 is disposed, is injected into the sealing cavity formed by the bottom cover 20 and the support 11 through the glue injection holes 119, and after the glue fixation is finished, the power module 12 is sealed in the sealing cavity.

Referring to fig. 5 to 11, the electrode module 13 includes a plurality of electrode plates 131 and insulating washers 132 sequentially stacked, the electrode plates 131 and the insulating washers 132 are all circular plates, and the electrode plates 131 and the insulating washers 132 have the same shape, wherein the electrode plates 131 have a thickness of 0.5mm to 1.5mm, the insulating washers 132 have a thickness of 0.1 mm to 2mm, and both the electrode plates 131 and the insulating washers 132 are parallel to the second surface of the support 11. In this embodiment, the thickness of the electrode plate 131 is 1mm, and the thickness of the insulating washer 132 is 0.8 mm.

The electrode plate 131 includes a plurality of first electrode plates 1311 and second electrode plates 1312 alternately stacked, the first electrode plates 1311 and the second electrode plates 1312 have opposite polarities, and the first electrode plates 1311 and the second electrode plates 1312 having opposite polarities are capable of electrolyzing water to generate hydrogen ions and oxygen ions, respectively, to purify food.

Since the polarities of first electrode plate 1311 and second electrode plate 1312 are opposite, insulating gasket 132 is disposed between each two adjacent first electrode plate 1311 and second electrode plate 1312 to isolate first electrode plate 1311 from second electrode plate 1312.

The electrode plate 131 is oppositely provided with a first electrode hole 1313 and a second electrode hole 1314, wherein the aperture size of the first electrode hole 1313 is smaller than that of the second electrode hole 1314, the position of the first electrode hole 1313 on the first electrode plate 1311 corresponds to that of the second electrode hole 1314 on the second electrode plate 1312, and the position of the second electrode hole 1314 on the first electrode plate 1311 corresponds to that of the first electrode hole 1313 on the second electrode plate 1312.

In addition, two guide holes 1322 are oppositely disposed on the insulating gasket 132, the two guide holes 1322 correspond to the first electrode hole 1313 and the second electrode hole 1314, respectively, and the aperture size of the guide holes 1322 is equal to or larger than the aperture size of the second electrode hole 1314.

The electrode module 13 further includes a first electrode post 133 and a second electrode post 134 electrically connected to the power module 12, the first electrode post 133 is disposed in the first electrode holes 1313 of the plurality of first electrode plates 1311, the second electrode post 134 is disposed in the first electrode holes 1313 of the plurality of second electrode plates 1312, and the first electrode post 133 is disposed in the plurality of first electrode holes 1313 without contacting the second electrode holes 1314 of the second electrode plates 1312 when passing through the plurality of first electrode holes 1313, and the second electrode post 134 is disposed in the plurality of first electrode holes 1313 without contacting the second electrode holes 1314 of the first electrode plates 1311 when passing through the plurality of first electrode holes 1313. The first electrode plates 1311 are electrically connected to the first electrode column 133, the second electrode plates 1312 are electrically connected to the second electrode column 134, and the first electrode column 133 and the second electrode column 134 can be electrically connected to the positive electrode and the negative electrode of the power module 12, respectively.

Referring to fig. 9, in order to enable water to rapidly contact the electrode plate 131, a plurality of first through holes 1315 are formed in the electrode plate 131, and the water enters the electrode plate 131 through the first through holes 1315.

Referring to fig. 7, fig. 7 is a schematic view illustrating a state of the portable food safety machine in which the insulating washer is installed, in order to facilitate water to rapidly enter an adjacent electrode plate 131 through the insulating washer 132 after passing through one of the electrode plates 131, a plurality of second through holes 1321 are formed in the insulating washer 132, wherein the size of the second through holes 1321 is larger than that of the first through holes 1315. In this embodiment, the electrode plate 131 is made of a titanium plate having good conductivity, the surface of the electrode plate 131 is uniformly coated with a silver coating, and the insulating washer 132 is made of plastic.

Referring to fig. 7 to 9, fig. 8 is a schematic view showing a state of mounting an electrode plate in the portable food safety machine according to the present embodiment, fig. 9 is a schematic view showing a state of mounting an electrode plate in the portable food safety machine according to the present embodiment, the electrode plate 131 and the insulating washer 132 may be fixed to an end surface of the supporter 11 by a connection method such as adhesion or snap-fit, in the present embodiment, a plurality of fastening holes 135 are formed in circumferential surfaces of the electrode plate 131 and the insulating washer 132, and the electrode plate 131 and the insulating washer 132 may be fixed to the end surface of the supporter 11 by sequentially inserting fastening members (not shown) into the plurality of fastening holes 135. In the present embodiment, the number of the fastening holes 135 is four, and it is understood that the number of the fastening holes 135 may be two, three or more in other embodiments not shown.

The end face of the support member 11, on which the electrode module 13 is disposed, is further provided with a power switch 15, the power switch 15 is electrically connected to the power module 12, and the power switch 15 is turned on to electrically connect the electrode module 13 and the power module 12. In the present embodiment, the power switch 15 is a push switch.

In the present invention, the power switch 15 is disposed on the supporting member 11 in order to enhance the aesthetic appearance of the food safety machine, and it is understood that the power switch 15 may be disposed on the surface of the bottom cover 20 in other embodiments.

Referring to fig. 5 and 6, the upper cover 30 is detachably disposed at one end of the supporting member 11 away from the bottom cover 20, and it can be understood that the connection manner between the upper cover 30 and the supporting member 11 can be a detachable connection manner such as a threaded connection or a bolt connection, in this embodiment, a lower end portion of the bottom cover 20 partially exceeds an outer peripheral surface of the supporting member 11 to form a limiting portion 17, a plurality of buckles 16 are disposed on the outer peripheral surface of the supporting member 11, the buckles 16 are disposed near the limiting portion 17, each buckle 16 is L-shaped, each buckle 16 includes a first buckle strip 161 and a second buckle strip 162 connected with each other, each of the first buckle strips 161 and the second buckle strips 162 is rectangular strip-shaped, the first buckle strip 161 is disposed along a circumferential direction of the supporting member 11, the second buckle strip 162 is disposed along an axial direction of the supporting member 11, one end of the second buckle strip 162 is connected with one end of the first buckle strip 161, the other end of the second buckle strip 162 is connected with, The space between the second clamping strip 162 and the limiting portion 17 forms a clamping groove 18, and an opening end 181 is formed on one side of the clamping groove 18 opposite to the second clamping strip 162.

The inner side surface of the upper cover 30 is provided with a plurality of clamping blocks 33 respectively corresponding to the buckles 16, the clamping blocks 33 are arranged along the circumferential direction of the upper cover 30, the clamping blocks 33 can be clamped in the clamping grooves 18, and the upper end surfaces of the clamping blocks 33 abut against the limiting parts 17, so that the upper cover 30 is fixed on the supporting part 11. In the present embodiment, the latch 16 and the latch 33 are made of plastic, the latch 16 is integrally formed with the support 11, and the latch 33 is integrally formed with the upper cover 30.

In this embodiment, the latch 33 and the slot 18 are tightly fitted, so that the latch 33 is not easy to automatically slide out after being clamped in the slot 18.

The shell surface of the upper cover 30 is provided with a plurality of through holes 31 communicated with the containing cavities, the aperture size of the through holes 31 is smaller than that of the first through holes 1315, impurities passing through the through holes 31 can pass through the first through holes 1315 without blocking the first through holes 1315, and the electrolytic effect of the electrode plate 131 is prevented from being influenced.

In addition, referring to fig. 10 and fig. 11, circular holes (not shown) are formed in the electrode plates 131, the circular holes of the plurality of electrode plates 131 penetrate through the second positioning holes 1316, a second positioning post 32 corresponding to the second positioning hole 1316 is protruded from the center of the upper cover 30, the second positioning post 32 is disposed toward the direction of the supporting member 11, in this embodiment, the second positioning post 32 is cylindrical, and the corresponding second positioning hole 1316 is a circular hole.

When the upper cover 30 is installed, the second positioning column 32 passes through the second positioning hole 1316 and then is connected to the first positioning column 21 passing through the first positioning hole 116, and it should be understood that the connection manner between the first positioning column 21 and the second positioning column 32 may be a connection manner such as a threaded connection or a snap connection, which is not limited herein.

In addition, through holes (not shown) are formed in the middle of the first positioning column 21 and the second positioning column 32, the through holes respectively penetrate through the upper cover 30 and the bottom cover 20, and the through holes in the first positioning column 21 and the through holes in the second positioning column 32 are communicated to form water leakage holes 34.

A charging port 321 is disposed in the through hole of the second positioning post 32, a first charging electrode 322, a second charging electrode 323 and an insulating sheet 324 disposed between the first charging electrode 322 and the second charging electrode 323 are disposed at the charging port 321, the polarities of the first charging electrode 322 and the second charging electrode 323 are opposite, the first charging electrode 322 and the second charging electrode 323 are respectively electrically connected to the power module 12, and when the first charging electrode 322 and the second charging electrode 323 are communicated with a charger, the power module 12 can be charged.

It is understood that the first charging electrode 322, the second charging electrode 323, and the insulation sheet 324 may be connected to the second positioning pillar 32 by bonding or screwing, and is not limited herein.

A plurality of air inlet holes 325 are formed in the circumferential surface of the second positioning column 32 and close to the bottom of the upper cover 30, the air inlet holes 325 are communicated with the containing cavity and the external environment, when the power module 12 needs to be charged, an electric fan is adopted to ventilate the containing cavity through the air inlet holes 325, air in the containing cavity is led to the outside through the through holes 31, air circulation is formed, and moisture in the containing cavity can be dried.

The operation of the portable food safety machine of the present invention will be described with reference to the accompanying drawings.

During installation, the power module 12 is placed in the fixing groove 114, the electric control board 14 is placed above the power module 12, the bottom cover 20 is hermetically covered on the safety machine body 10, glue is injected into the accommodating cavity through the glue injection hole 119, and the power module 12 is sealed in the sealing cavity.

The plurality of electrode plates 131 and the plurality of insulating gaskets 132 are sequentially stacked and fixedly arranged on the end face of the safety machine body 10, the first electrode columns 133 and the second electrode columns 134 are respectively arranged in the first electrode holes 1313 of the plurality of first electrode plates 1311 and the first electrode holes 1313 of the second electrode plates 1312 in a penetrating manner, the power switch 15 is turned on, the second positioning columns 32 of the upper cover 30 are inserted into the second positioning holes 1316 and connected with the first positioning columns 21, the upper end faces of the fixture blocks 33 of the upper cover 30 are abutted against the limiting parts 17, the fixture blocks 33 are aligned with the opening ends 181, the upper cover 30 is rotated, the fixture blocks 33 are clamped in the clamping grooves 18, and the portable food safety machine can be used after being installed and being immersed in water.

Due to the gravity action of the power module 12, the portable food safety machine is completely immersed in water, so that each part of the electrode plate 131 can electrolyze water to generate hydrogen ions and oxygen ions, and the hydrogen ions and the oxygen ions in the accommodating cavity flow into the water from the through holes 31 and purify food, and the purification efficiency is high. Compared with other mounting modes of the electrode module 13, such as vertical or inclined arrangement relative to the end face of the support 11, the electrode module 13 of the embodiment is arranged in parallel relative to the second plane of the support 11, so that the portable food safety machine is small in size and convenient to carry.

According to the portable food safety machine, the power supply module 12 is arranged in the sealing cavity between the bottom cover 20 and the support piece 11, the electrode module 13 electrically connected with the power supply module 12 is arranged in the accommodating cavity between the upper cover 30 and the support piece 11, the portable food safety machine is immersed in water for electrolyzing water, the sealing cavity is of a glue injection structure, the sealing effect is good, and meanwhile, the electrode module 13 is arranged in parallel relative to the support piece 11, so that the portable food safety machine is small in size and convenient to carry.

In one example, the water level detecting component is a liquid level detector, or the water level detecting component is a pressure sensor, and is disposed on an end surface of the safety machine body 10 facing the upper cover 30; and determining the liquid level value according to the pressure value detected by the pressure sensor. Wherein, the pressure value that pressure sensor detected is positive correlation with the liquid level value, and its corresponding relation is stored in food safety machine.

Optionally, when the liquid level value detected by the water level detection assembly reaches a predetermined liquid level, the electric control plate determines that the electrolysis condition is met, and controls the electrode module 13 to perform electrolysis work; when the level value detected by the water level detection assembly is lower than the predetermined level, the control electrode module 13 stops the motor. The predetermined liquid level may be set by a system developer, and the predetermined liquid level is generally lower than a distance from the upper cover to the safety machine body when the upper cover covers the safety machine body, for example, the predetermined liquid level may be set by the system developer to be half of the distance.

In another example, the water level detecting assembly 19 includes two sensing electrodes (not shown), and a resistance detecting device (not shown) for detecting the resistance between the two sensing electrodes, wherein the resistance detecting device is electrically connected to the electric control board. Water can enter the receiving cavity from the escape hole 31 when the food safety machine is thrown into water, resulting in a decrease in the resistance value between the two sensing electrodes.

Optionally, when the resistance value detected by the resistance value detection device is lower than a predetermined resistance value, the electric control board controls the electrode module 13 to perform electrolysis work; and when the resistance value detected by the resistance value detection device is higher than the preset resistance value, controlling the electrolysis module to stop electrolysis. Wherein the predetermined resistance value is set by a system developer.

In the present invention, the power switch 15 is provided on the safety device body 10 in order to enhance the aesthetic appearance of the food safety device, but it should be understood that the power switch 15 may be provided on the surface of the bottom cover 20 in other embodiments.

The following describes the use of the food safety machine of the present invention with reference to the accompanying drawings.

The bottom cover 20 is covered on the safety machine body 10, a plurality of electrode plates are sequentially stacked and fixedly arranged on the end face, far away from the bottom cover 20, of the safety machine body 10, the positioning column 32 of the upper cover 30 is inserted into the positioning hole 14, the clamping block 33 of the upper cover 30 is mutually clamped with the clamping buckle 16 on the safety machine body 10, the upper cover 30 is covered on the safety machine body 10, the food safety machine is formed, and the food safety machine can be used after being thrown into water.

Because the aperture of the dissipation hole 31 is small, only water and very small impurities can enter the accommodating cavity through the dissipation hole 31 and then enter the electrode module 13, the electrode module 13 electrolyzes the water, hydrogen ions and oxygen ions generated by the electrolyzed water flow out through the dissipation hole 31 and purify food in the water, and when the very small impurities enter the electrode module 13 through the dissipation hole 31, the very small impurities can pass through the dissipation hole because the aperture size of the dissipation hole 31 is larger than that of the dissipation hole 31.

When the food safety machine is thrown into water, because electrode module 13 is located the terminal surface center of safety machine body 10, rely on the focus effect of electrode module 13 to make food safety machine's upper cover 30 immerse the aquatic completely, because the electrode plate is on a parallel with the terminal surface setting of safety machine body 10 for the electrode plate immerses in water completely, makes every position of electrode plate all can the brineelectrolysis produce hydrogen ion and oxygen ion, and the electrolysis effect is higher.

According to the food safety machine, the electrode plates are sequentially stacked in the accommodating cavities formed by the upper cover 30 and the safety machine body 10, the electrode plates are provided with the plurality of through holes so that water can pass through the electrode plates, and meanwhile, the aperture size of the dissipation holes 31 formed in the upper cover 30 is smaller than that of the through holes, so that impurities passing through the dissipation holes 31 can pass through the through holes without blocking the through holes, the electrolytic effect of the electrode plates is improved, the structure is simple, the use is convenient, and the food safety machine is suitable for popularization and use.

In light of the foregoing description of preferred embodiments in accordance with the invention, it is to be understood that numerous changes and modifications may be made by those skilled in the art without departing from the scope of the invention. The technical scope of the present invention is not limited to the contents of the specification, and must be determined according to the scope of the claims.

Claims

1. The utility model provides a food safety machine, its characterized in that, food safety machine includes that the safety machine body, lid are established upper cover, electrode module, water level detection subassembly and automatically controlled board on the safety machine body, wherein:

2. The food safety machine according to claim 1, wherein the water level detection assembly is a liquid level detector, or the water level detection assembly comprises two sensing electrodes, and a resistance value detection device for detecting the resistance between the two sensing electrodes.

3. The food safety machine according to claim 2, wherein the electric control board controls the electrode module to perform electrolysis operation when it is determined that the electrolysis condition is satisfied based on the information detected by the water level detection assembly, including:

or,

4. The food safety machine according to claim 2,

the electric control board also controls the electrode module to stop the electrolytic work when the liquid level value detected by the liquid level detector is lower than a preset liquid level; or,

5. The food safety machine according to claim 2, wherein the liquid level detector is provided on an end face of the safety machine body facing the upper cover.

6. The food safety machine according to claim 1, wherein a power switch is further disposed on an end surface of the safety machine body located in the receiving cavity, wherein:

7. The food safety machine according to claim 1, wherein the plurality of electrode plates are sequentially stacked, and each two adjacent electrode plates have opposite polarities.

8. The food safety machine according to claim 1, wherein the electrode plate is disposed parallel to an end face of the safety machine body.

9. The food safety machine according to claim 1, wherein a plurality of mounting holes are formed in the peripheral surface of the electrode plate, and a fastening member is inserted into the mounting holes to fix the electrode plate to the end surface of the safety machine body.

10. The food safety machine as claimed in claim 1, wherein the electrode plate is provided with through holes, a plurality of the through holes are formed through the through holes to form positioning holes, and the upper cover is provided with positioning posts protruding corresponding to the positioning holes.