阅读说明：本技术 食品净化机 (Food purifier ) 是由 宋金鸿 于 2017-12-31 设计创作，主要内容包括：本发明涉及一种食品净化机。所述食品净化机包括主机体与电解模组,所述主机体上开设有净化槽,所述主机体于所述净化槽内或者于所述净化槽的一侧形成有至少一个插设槽,所述至少一个插设槽与所述净化槽连通,所述电解模组包括相对设置的第一阳极板与第一阴极板,所述第一阳极板与所述第一阴极板可拆卸地插设于所述至少一个插设槽中,以与所述主机体电性连接。所述食品净化机能够避免食品的交叉污染。(The invention relates to a food purifier. Food purification machine includes the host computer body and electrolysis module, the purification groove has been seted up on the host computer body, the host computer body in purify the inslot or in one side of purifying the groove is formed with at least one and inserts and establishes the groove, at least one insert establish the groove with purify the groove intercommunication, the electrolysis module is including the relative first anode plate and the first negative plate that sets up, first anode plate with first negative plate detachably inserts and locates at least one is inserted and is established in the groove, with host computer body electric connection. The food purifier can avoid cross contamination of food.)

1. A food purifier is characterized by comprising a main machine body and an electrolysis module, wherein the main machine body is provided with a purification tank, the main machine body is arranged in the purification tank or is provided with at least one insertion tank on one side of the purification tank, the at least one insertion tank is communicated with the purification tank, the electrolysis module comprises a first anode plate and a first cathode plate which are oppositely arranged, and the first anode plate and the first cathode plate are detachably inserted in the at least one insertion tank so as to be electrically connected with the main machine body;

the main machine body comprises a box body and a functional module arranged on one side in the box body, the purification tanks are formed in the box body and are positioned on one side of the functional module, at least one insertion groove is formed in the functional module, the number of the insertion grooves is two, the two purification tanks are arranged at intervals, the electrolysis module further comprises a connecting frame, and the first negative plate and the first positive plate are convexly arranged on the connecting frame and are respectively detachably inserted in the two insertion grooves;

the electrolytic module further comprises a second anode plate, a second cathode plate and a driving mechanism, wherein the first anode plate and the first cathode plate form a first working group, the second anode plate and the second cathode plate form a second working group, the first working group and the second working group both have an idle state and a working state, the idle state is a folding state or a hiding state, the working state is an extending state or an exposing state, the driving mechanism is used for enabling the first working group and the second working group to be switched into the working state, the first working group can be enabled to enter the working state through the driving mechanism, the second working group is in the idle state, or the second working group can be enabled to enter the working state, and the first working group is in the idle state, namely the first working group and the second working group are always in different working states.

2. The food purifier of claim 1, wherein the electrolysis module further comprises a connecting frame, the first anode plate and the first cathode plate are spaced apart from each other and disposed on the connecting frame, and the second anode plate and the second cathode plate are spaced apart from each other and disposed on the connecting frame.

3. The food purifier of claim 2, wherein the driving mechanism is disposed on the connecting frame, the first anode plate, the second anode plate, the first cathode plate and the second cathode plate are connected to the driving mechanism, and the driving mechanism can be unfolded to enter water by stretching the first anode plate and the first cathode plate, so as to enable the first working group to enter the working state, or can be unfolded to enter water by exposing the first anode plate and the first cathode plate to enter the working state.

4. The food purifier of claim 3, wherein the first cathode plate and the second cathode plate are parallel to each other, the first cathode plate comprises a first plate body and a first cover plate, the second cathode plate comprises a second plate body and a second cover plate, the first plate body and the second plate body are clamped between the first cover plate and the second cover plate, the first cover plate and the second cover plate are both connected with a driving mechanism, the driving mechanism is used for driving the first cover plate to rotate so as to expose the first plate body, and the driving mechanism is also used for driving the second cover plate to rotate so as to expose the second plate body.

5. The food purifier of claim 4, wherein the first cathode plate, the second cathode plate, the first anode plate and the second anode plate are energized, and the first cathode plate and the first anode plate are exposed to water by the drive mechanism, such that substantially only the first working group is brought into operation, or wherein the second working group is energized while the drive mechanism drives the first working group into operation.

6. The food purifier of claim 5, wherein the electrolysis module further comprises a first separator plate sandwiched between the first cathode plate and the second cathode plate, opposite sides of the first separator plate being attached to the first cathode plate and the second cathode plate, respectively.

Technical Field

The invention relates to a food purifier.

Background

The existing food can have residual pesticide, hormone or virus, and the health of consumers can be affected after long-term consumption. Therefore, various brands of purifier products appear in the market, such as the brand of Baoan, the brand of Cai Bao, the brand of one hundred and one hundred good-success clean core and the like. The water is electrolyzed by the electrolytic module, that is, the water is electrolyzed by the cathode electric plate and the anode electric plate to generate ionized water, and the ionized water is used for cleaning the substances such as pesticides, hormones or viruses on the food. However, when the food purifier purifies the meat for multiple times, grease left in the meat easily pollutes the electrolysis module, and when vegetables are purified subsequently, the grease on the electrolysis module flows into water, so that the vegetables are polluted, and cross contamination is caused.

Disclosure of Invention

Based on this, there is a need for a food purifier that can avoid cross-contamination.

The utility model provides a food purifier, includes the host computer body and electrolysis module, the purification groove has been seted up on the host computer body, the host computer body in purify in the groove or in one side of purifying the groove is formed with at least one and inserts and establishes the groove, at least one insert establish the groove with purify the groove intercommunication, the electrolysis module is including the relative first anode plate and the first negative plate that sets up, first anode plate with first negative plate detachably inserts and locates at least one is inserted and is established in the groove, with host computer body electric connection.

In one embodiment, the main body includes a housing and a function module disposed at one side of the housing, the purge tank is formed in the housing and located at one side of the function module, and the at least one insertion groove is formed at the function module.

In one embodiment, the number of the insertion grooves is two, the two purification grooves are arranged at intervals, the electrolysis module further comprises a connecting frame, and the first cathode plate and the first anode plate are convexly arranged on the connecting frame and are respectively detachably inserted into the two insertion grooves.

In one embodiment, the device further comprises an inner accommodating basket movably accommodated in the purifying tank, and the at least one inserting groove is formed in the inner accommodating basket and located in the purifying tank.

In one embodiment, the inner receiving basket includes a receiving body and an annular rib protruding from a periphery of the receiving body, the number of the at least one insertion groove is two, the two insertion grooves are oppositely opened on the annular rib, and the first cathode plate and the first anode plate are respectively detachably inserted into the two insertion grooves.

In one embodiment, the electrolysis module further includes a second anode plate, a second cathode plate and a driving mechanism, the first anode plate and the first cathode plate form a first working group, the second anode plate and the second cathode plate form a second working group, the first working group and the second working group both have an idle state and a working state, the idle state is a folded or concealed state, the working state is an extended or exposed state, and the driving mechanism is configured to selectively switch the first working group and the second working group into the working state.

In one embodiment, the electrolysis module further includes a connecting frame, the first anode plate and the first cathode plate are disposed on the connecting frame at intervals, the second anode plate and the second cathode plate are disposed on the connecting frame at intervals, the driving mechanism is disposed on the connecting frame, and the first anode plate, the second anode plate, the first cathode plate and the second cathode plate are all connected to the driving mechanism.

In one embodiment, the first negative plate and the second negative plate are parallel to each other, the first negative plate includes a first plate body and a first cover plate, the second negative plate includes a second plate body and a second cover plate, the first plate body and the second plate body are clamped between the first cover plate and the second cover plate, the first cover plate and the second cover plate are both connected with the driving mechanism, the driving mechanism is configured to drive the first cover plate to rotate so as to expose the first plate body, and the driving mechanism is further configured to drive the second cover plate to rotate so as to expose the second plate body.

In one embodiment, the electrolysis module further comprises a first isolation plate, the first isolation plate is clamped between the first cathode plate and the second cathode plate, and two opposite sides of the first isolation plate are respectively attached to the first cathode plate and the second cathode plate.

In one embodiment, the first cathode plate is a corrugated plate, the electrolysis module further comprises a first elastic pulling and holding piece, the first elastic pulling and holding piece is arranged on the connecting frame and pulls and holds the first cathode plate to contract, and the driving mechanism is used for driving the first cathode plate to extend.

When the food purifier is used, meat products are firstly placed in the purifying tank, and then the water is electrolyzed by the electrolysis module to generate ionized water, so that the meat products are purified by the ionized water. When the fruit and vegetable food is required to be purified, the first anode plate and the first cathode plate are pulled out, and the anode plate and the cathode plate which are replaced by new plates are inserted into the inserting groove, so that the first anode plate and the first cathode plate are prevented from being polluted by oil released in water by the meat food, the oil is prevented from further polluting the fruit and vegetable food, and the cross contamination of the meat and the fruit and vegetable food can be avoided.

Drawings

Fig. 1 is a schematic perspective view of a food purifier according to an embodiment.

Fig. 2 is a perspective view of an electrolysis module of the food purifier shown in fig. 1.

Fig. 3 is a schematic perspective view of a food purifier according to an embodiment.

Fig. 4 is a perspective view of the mounting bracket shown in fig. 3.

FIG. 5 is a perspective view of an electrolytic module according to an embodiment.

FIG. 6 is a schematic perspective view of an electrolysis module according to another embodiment.

FIG. 7 is a schematic perspective view of an electrolytic module according to still another embodiment

Fig. 8 is a partial enlarged view of a portion a in fig. 7.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The invention relates to a food purifier. For example, the food purifier comprises a main body and an electrolysis module, wherein the main body is provided with a purification tank, and the main body is arranged in the purification tank or is provided with at least one insertion groove on one side of the purification tank. For example, the at least one insertion groove is communicated with the purification groove, and the electrolysis module comprises a first anode plate and a first cathode plate which are oppositely arranged. For example, the first anode plate and the first cathode plate are detachably inserted into the at least one insertion groove to be electrically connected with the main body.

Referring to fig. 1 and 2, a food purifier 100 comprises a main body 30 and an electrolysis module 50, wherein a purification tank 31 is disposed on the main body 30, the main body 30 is disposed in the purification tank 31 or at least one insertion groove 33 is formed on one side of the purification tank 31, the at least one insertion groove 33 is communicated with the purification tank 31, the electrolysis module 50 comprises a first anode plate 51 and a first cathode plate 53 which are oppositely disposed, and the first anode plate 51 and the first cathode plate 53 are detachably inserted in the at least one insertion groove 33 to be electrically connected with the main body 30.

For example, when the food purifier 100 is used, meat is first put into the purifying tank 31, and then water is electrolyzed by the electrolysis module 50 to generate ionized water, so that the meat is purified by the ionized water. When fruit and vegetable food needs to be purified, the first anode plate 51 and the first cathode plate 53 are pulled out, and the new anode plate and the new cathode plate are replaced to be inserted into the inserting groove 33, so that the first anode plate 51 and the first cathode plate 53 are prevented from being polluted by grease released by the meat food in water, the grease is prevented from further polluting the fruit and vegetable food, and cross contamination between the meat and the fruit and vegetable food can be avoided, namely the first anode plate 51 and the first cathode plate 53 can be specially used for purifying the meat, and can also be cleaned and then used for purifying the fruit and vegetable food. For example, the inserted first anode plate 51 and the inserted first cathode plate 53 can be electrically connected to the power supply of the main body 30.

For example, in order to facilitate the insertion of the first cathode plate 53 and the first anode plate 51, the main body 30 includes a box 32 and a function module 34 disposed at one side in the box 32, for example, the function module 34 is a circuit or waterway driving module of the main body 30. The purge tank 31 is formed in the case 32 at one side of the function module 34, and the at least one insertion groove 33 is formed on the function module 34. The number of the insertion grooves 33 is two, the two purification grooves 31 are arranged at intervals, the electrolysis module 50 further comprises a connecting frame 52, and the first cathode plate 53 and the first anode plate 51 are convexly arranged on the connecting frame 52 and are respectively detachably inserted into the two insertion grooves 33. The insertion grooves 33 are formed in the functional module 34, so that the main body 30 can be slightly modified, and the first anode plate 51 and the first cathode plate 53 can be firmly fixed by the two insertion grooves 33. The functional module 34 has a positioning groove 341 recessed on the surface thereof, and the two insertion grooves 33 are opened on the bottom surface of the positioning groove 341, for example, the first anode plate 51 and the first cathode plate 53 are both fixed on the connecting frame 52, and the connecting frame 52 is received and positioned in the positioning groove 341. Two electrical connection holes 521 are formed in one side of the connecting frame 52 and are respectively used for electrically connecting the first anode plate 51 and the first cathode plate 53, a pressing component 35 is further arranged on one side of the box body 32, the pressing component 35 comprises a button 351 and a pressing frame 353, the button 351 is movably arranged on the side wall of the box body, the pressing frame 353 is arranged in the functional module 34 and abuts against the button 351, two electrical connection columns 3531 are convexly arranged on one side of the pressing frame 353, and the two electrical connection columns 3531 are elastically inserted into the two electrical connection holes 521 so as to be respectively electrically connected with the first anode plate 51 and the first cathode plate 53. By pressing the button 351, the two elastic connection posts can be ejected out of the two electrical connection holes 521, so that the first cathode plate 53 and the first anode plate 51 can be pulled out.

Referring to fig. 3 and 4, a mounting frame 36 is further disposed in the purification tank 31, the mounting frame 36 divides the purification tank 31 into at least two classification tanks 311, the insertion tank 33 is formed in the mounting frame 36 and includes a first insertion tank and a second insertion tank, and the first insertion tank and the second insertion tank are respectively communicated with the two classification tanks 311. The electrolysis module 50 further comprises a second cathode plate 55 and a second anode plate 56 which are oppositely arranged, the first cathode plate 53 and the first anode plate 51 are both arranged in the first inserting groove, the second cathode plate 55 and the second anode plate 56 are both arranged in the second inserting groove, so that the first cathode plate 53 and the first anode plate 51 can be used for carrying out electrolysis operation on one of the classification grooves 311, and the second cathode plate 55 and the second anode plate 56 are used for carrying out electrolysis operation on the other classification groove 311. For example, one of the sorting tanks 311 is a meat purifying tank, and the other sorting tank 311 is a fruit and vegetable purifying tank. For example, the mounting frame 36 includes an isolation plate 361 and an insertion plate 363 that are arranged in a cross manner, the isolation plate 361 isolates the two classification grooves 311, the first insertion groove and the second insertion groove are both disposed on the insertion plate 363 and are respectively located at two opposite sides of the isolation plate 361, two opposite ends of the insertion plate 363 are respectively protruded into the two classification grooves 311 to divide the classification grooves 311 into two sub-grooves 3113, and a plurality of electrolysis through holes 3631 are formed through a side wall of the insertion plate 363, so that the two sub-grooves 3113 are communicated. For example, the first cathode plate 53, the first anode plate 51, the second cathode plate 55 and the second anode plate 56 are all provided with through holes to facilitate the communication between the two corresponding sub-slots 3113. For example, the insertion plate 363 and the isolation plate 361 are perpendicular to each other.

Referring to fig. 5, for example, in order to facilitate cleaning of the first anode plate 51 and the first cathode plate 53, the food purifier 100 further includes an inner receiving basket 60, the inner receiving basket 60 is movably received in the purifying tank 31, and the at least one inserting groove 33 is opened on the inner receiving basket 60 and is located in the purifying tank 31. The accommodating inner basket 60 comprises an accommodating body 61 and an annular rib 63 protruding from the periphery of the accommodating body 61, the number of the at least one insertion groove 33 is two, and the two insertion grooves 33 are oppositely arranged on the annular rib 63. When in use, the accommodating inner basket 60 is arranged at the bottom of the purifying tank 31, and then the first anode plate 51 and the first cathode plate 53 are respectively inserted into the two insertion grooves 33. Of course, the first anode plate 51 and the first cathode plate 53 may be inserted into the inner basket 60 in advance, and then the inner basket 60 may be placed into the purification tank 31.

Referring to fig. 6, for example, in order to conveniently and switchably adopt different electrode plates to respectively purify meat and vegetable food, the electrolysis module 50 further includes a second anode plate 56, a second cathode plate 55 and a driving mechanism 58, the first anode plate 51 and the first cathode plate 53 form a first working group, the second anode plate 56 and the second cathode plate 55 form a second working group, both the first working group and the second working group have an idle state and a working state, the idle state is a folded or hidden state, the working state is an extended or exposed state, and the driving mechanism 58 is configured to switch the first working group and the second working group into the working state. By means of the drive mechanism 58, the first working group can be brought into an operating state, the second working group being in an idle state, or the second working group can be brought into an operating state, the first working group being in an idle state. I.e. the first working group and the second working group are always in different working states.

For example, in order to facilitate driving the first working group and the second working group into the working state, the electrolysis module 50 further includes a connecting frame 52, the first anode plate 51 and the first cathode plate 53 are disposed on the connecting frame 52 at intervals, the second anode plate 56 and the second cathode plate 55 are disposed on the connecting frame 52 at intervals, the driving mechanism 58 is disposed on the connecting frame 52, and the first anode plate 51, the second anode plate 56, the first cathode plate 53 and the second cathode plate 55 are all connected to the driving mechanism 58. The drive mechanism 58 may be deployed by stretching the first anode plate 51 and the first cathode plate 53 into the water to bring the first working group into the working state, or may be deployed by exposing the first anode plate 51 and the first cathode plate 53 to the water to bring the first working group into the working state. The connection of the first anode plate 51, the second anode plate 56, the first cathode plate 53 and the second cathode plate 55 to the circuit belongs to the conventional technical means in the field, and is not described herein again.

For example, in order to facilitate the exposure of the first working group or the second working group, the first cathode plate 53 and the second cathode plate 55 are disposed in parallel, the first cathode plate 53 includes a first plate body 531 and a first cover plate 533, the second cathode plate 55 includes a second plate body 551 and a second cover plate 553, the first plate body 531 and the second plate body 551 are sandwiched between the first cover plate 533 and the second cover plate 553, both the first cover plate 533 and the second cover plate 553 are connected to the driving mechanism 58, the driving mechanism 58 is configured to drive the first cover plate 533 to rotate to expose the first plate body 531, and the driving mechanism 58 is further configured to drive the second cover plate 553 to rotate to expose the second plate body 551. For example, the first cathode plate 53, the second cathode plate 55, the first anode plate 51, and the second anode plate 56 are energized, and the first cathode plate 53 and the first anode plate 51 are exposed to water by the drive mechanism 58, so that only the first working group actually enters the working state. Or, when the driving mechanism 58 drives the first working group to enter the working state, the second working group is electrically connected. By arranging the first cover plate 533 and the second cover plate 553, the implementation manner of the first workgroup entering the working state is simple.

For example, in order to facilitate the insulation, the first cathode plate 53, the first anode plate 51, the second anode plate 56 and the second cathode plate 55, the electrolysis module 50 further includes a first isolation plate sandwiched between the first cathode plate 53 and the second cathode plate 55, and two opposite sides of the first isolation plate are respectively attached to the first cathode plate 53 and the second cathode plate 55. Since the first separator is disposed between the first cathode plate 53 and the second cathode plate 55, a good insulation effect can be achieved by the first separator.

Referring to fig. 7 and 8, for example, in order to make the first working group or the second working group enter a working state by stretching, the first cathode plate 53 is a corrugated plate, the electrolysis module 50 further includes a first elastic pulling member 57, the first elastic pulling member 57 is disposed on the connecting frame 52 and pulls the first cathode plate 53 to contract, and the driving mechanism 58 is used for driving the first cathode plate 53 to stretch. When the first cathode plate 53 is stretched into the water after stretching, the second cathode plate 55 is pulled to contract by the second elastic pulling member.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.