CN218942226U - Wireless double-head food material cleaning machine - Google Patents

Abstract

The utility model relates to the field of food material cleaning, and discloses a wireless double-head food material cleaning machine, which comprises the following steps: the charging device comprises a charging base, wherein a first positioning groove is formed in the charging base, a wireless power supply module is arranged on the lower side of the first positioning groove, and the wireless power supply module is magnetic; the cleaning assembly comprises a wireless power-on module, and when the cleaning assembly is placed in the first positioning groove, the wireless power-on module is connected with the wireless power-on module and supplies power, and the cleaning assembly and the charging base are magnetically attracted together. This wireless double-end food material cleaning machine disposes wireless power module and wireless power module for wash the subassembly and charge the mode power supply that the base accessible is wireless charges, and the design of first constant head tank has then guaranteed to wash between subassembly and the base that charges reliably to guarantee that wireless power module and wireless power module both fix a position reliably and carry out the transmission of electricity.

Description

Wireless double-head food material cleaning machine

Technical Field

The utility model relates to the field of food material cleaning, in particular to a wireless double-head food material cleaning machine.

Background

The charging mode of the existing wireless double-end food material cleaning machine mainly comprises wire charging, and the charging wire is required to be additionally stored and inserted, so that the operation is inconvenient.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art.

The utility model provides a wireless double-head food material cleaning machine, which comprises:

the charging device comprises a charging base, wherein a first positioning groove is formed in the charging base, a wireless power supply module is arranged on the lower side of the first positioning groove, and the wireless power supply module is magnetic;

the cleaning assembly comprises a wireless power-on module, and when the cleaning assembly is placed in the first positioning groove, the wireless power-on module is connected with the wireless power-on module and supplies power, and the cleaning assembly and the charging base are magnetically attracted together.

The utility model has the beneficial effects that: this wireless double-end food material cleaning machine disposes wireless power module and wireless power module for wash the subassembly and charge the mode power supply that the base accessible is wireless charges, and the design of first constant head tank has then guaranteed to wash between subassembly and the base that charges reliably to guarantee that wireless power module and wireless power module both fix a position reliably and carry out the transmission of electricity.

As some sub-schemes of the technical scheme, an electric bin is further arranged in the charging base, a power conversion port communicated to the outside is formed in the charging base, a bin cover is detachably connected to the power conversion port, and the electric bin is used for placing a battery for supplying power to the wireless power supply module.

As some sub-schemes of above-mentioned technical scheme, cleaning assembly includes top cap, bottom, ionization module, separator, power supply mainboard, top cap and bottom are connected and are formed the installation cavity, the separator is established in the installation cavity, the separator with the bottom is connected and is separated into mutually isolated logical water cavity and water proof cavity with the installation cavity, the power supply mainboard is established in the water proof cavity and with the separator is connected, be equipped with the conductive post on the power supply mainboard, the downside of conductive post is equipped with first double-screw bolt, the upper portion of conductive post is equipped with first screw, first screw bolt passes the power supply mainboard stretches out downwards and is connected with first nut, first nut will the conductive post lock is in the top surface of power supply mainboard, first screw bolt, conductive post, first screw are electric connection in proper order, the ionization module is located in the water cavity, be equipped with the through-hole on the ionization module, the through-hole department is equipped with first screw, first screw with first screw threaded connection, be equipped with between the head of first screw bolt and the through-hole seal circle.

As some sub-aspects of the above technical solution, the electrode sheet includes a power receiving portion and an ionization portion, the power receiving portion and the ionization portion are arranged in non-parallel to each other, and the power receiving portion and the ionization portion are connected as one body through a twisting portion.

As some sub-aspects of the above technical solution, the power receiving portion and the ionization portion are perpendicular to each other.

As some sub-aspects of the above technical solution, an area of a junction of the twisted portion and the ionized portion is 3 times or more the thickness of the ionized portion.

As some sub-schemes of the above technical scheme, the area of the connection part of the twisted part and the power receiving part is more than 3 times of the thickness of the ionization part.

As some sub-schemes of the above technical scheme, the ionization module further comprises an upper cover and a lower cover, the number of the electrode plates is two, and the two electrode plates are arranged between the upper cover and the lower cover.

As some sub-schemes of the technical scheme, the two electrode plates are respectively a positive plate and a negative plate, the difference between the positive plate and the negative plate is that the relative positions of the power connection part and the ionization part are different, the two sides of the lower cover are respectively provided with a positive positioning groove and a negative positioning groove, the positive plate is positioned in the positive positioning groove, and the negative plate is positioned in the negative positioning groove.

As some sub-schemes of the technical scheme, the upper cover is also provided with a positive electrode mark and a negative electrode mark.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of an embodiment of a wireless dual head food material washer;

FIG. 2 is a disassembled structure diagram of the wireless double-ended food material cleaning machine;

FIG. 3 is a schematic view of a partially cut-away structure of a wireless double-ended food material washer in the left-right direction;

FIG. 4 is a schematic view of a partially cut-away structure of a wireless double-ended food material washer in a front-to-rear direction;

FIG. 5 is a partial exploded view of the cleaning assembly;

fig. 6 is a schematic structural view of an electrode sheet;

FIG. 7 is an exploded view of an ionization module;

fig. 8 is a top view of an ionization module.

In the accompanying drawings: 1-cleaning an assembly; 101-a water isolation cavity; 102-a water cavity; 11-top cover; 12-a bottom cover; 13-an ionization module; 14-spacers; 15-a power supply main board; 16-a radio module; 171-conductive posts; 172-first studs; 173-a first nut; 174—first screw; 175-a water-proof sealing ring; 176-separating the sealing rings; 18-electrode sheet; 18 a-positive plate; 18 b-a negative plate; 181-an ionization section; 182-twist; 183-a power connection; 191-upper cover; 1911-positive identification; 1912-negative identification;

192-lower cover; 1921—positive positioning groove; 1922-a negative positioning groove;

2-a charging base; 21-an electric bin; 22-wireless power module.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, the meaning of a number is not quantitative, and the meaning of a number is two or more, and greater than, less than, exceeding, etc. are understood to exclude the present number, and the meaning of above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated. Appear throughout and/or represent three parallel schemes, e.g., a and/or B represent a scheme that is met by a, a scheme that is met by B, or a scheme that is met by a and B simultaneously.

In the description of the utility model, there are phrases containing a plurality of parallel features, where the phrase defines a feature that is closest, for example: b, C provided on A, E connected with D, which means that B is provided on A, E connected with D, and C is not limited; but for the words representing the relationship between features, such as "spaced arrangement", "annular arrangement", etc., do not belong to this category. The phrase preceded by a "homonym" indicates that all features in the phrase are defined, e.g., B, C, D, all disposed on a, and B, C and D are disposed on a. The sentence of the subject is omitted, and the omitted subject is the subject of the previous sentence, namely, B is arranged on A and comprises C, B is arranged on A, and A comprises C.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

Embodiments of the present utility model are described below with reference to fig. 1 to 8.

The embodiment relates to a wireless double-head food material cleaning machine, which comprises a charging base 2 and a cleaning assembly 1;

the charging base 2 is provided with a first positioning groove, the lower side of the first positioning groove is provided with a wireless power supply module 22, and the wireless power supply module 22 has magnetism;

the cleaning assembly 1 comprises a wireless power receiving module 16, when the cleaning assembly 1 is placed in the first positioning groove, the wireless power supply module 22 and the wireless power receiving module 16 are connected and supply power, and the cleaning assembly 1 and the charging base 2 are magnetically attracted together.

The wireless double-end food material cleaning machine is provided with the wireless power supply module 22 and the wireless power receiving module 16, so that the cleaning assembly 1 and the charging base 2 can supply power in a wireless charging mode, and the cleaning assembly 1 and the charging base 2 are reliably positioned by the design of the first positioning groove so as to ensure that the wireless power supply module 22 and the wireless power receiving module 16 reliably transmit power in a positioning mode.

The wireless power supply module 22 and the wireless power receiving module 16 have a power supply portion and a power receiving portion 183, which are included in the wireless charging structure in the prior art, and are generally all of a metal coil structure.

Further, an electrical bin 21 is further disposed in the charging base 2, a power exchanging port communicated to the outside is disposed on the charging base 2, a bin cover (not shown in the figure) is detachably connected to the power exchanging port, and the electrical bin 21 is used for placing a battery for supplying power to the wireless power supply module 22. The charging base 2 is internally provided with an electric bin 21 and a bin cover, and different batteries can be replaced by opening the bin cover, so that the charging base 2 can be conveniently moved and arranged.

Further, the cleaning assembly 1 comprises a top cover 11, a bottom cover 12, an ionization module 13, a spacer 14 and a power supply main board 15, wherein the top cover 11 and the bottom cover 12 are connected to form an installation cavity, the spacer 14 is arranged in the installation cavity, the spacer 14 is connected with the bottom cover 12 and separates the installation cavity into a water through cavity 102 and a water isolation cavity 101 which are isolated from each other, the power supply main board 15 is arranged in the water isolation cavity 101 and is connected with the spacer 14, a conductive column 171 is arranged on the power supply main board 15, a first stud 172 is arranged on the lower side of the conductive column 171, a first screw hole is arranged on the upper portion of the conductive column 171, the first stud 172 penetrates through the power supply main board 15 to downwards extend and is connected with a first nut 173, the first nut 173 locks the conductive column 171 on the top surface of the power supply main board 15, the first stud 172, the conductive column 171 and the first screw 174 are sequentially and electrically connected, the ionization module 13 is arranged in the water through cavity 102, a through hole 174 is arranged on the ionization module 13, a first screw hole 174 is arranged at the through hole, a first screw hole 174 is arranged between the first screw hole 174 and the first screw hole is connected with the first screw hole 175.

The top cover 11 and the bottom cover 12 are internally provided with a water passing cavity 102 and a water separating cavity 101 which are isolated from each other through a spacer 14, so that parts which cannot be immersed in water can be effectively separated. The first stud 172, the conductive post 171, and the first screw 174 are all metal pieces in this embodiment, and the first stud 172, the conductive post 171, and the first screw 174 are electrically connected in sequence, so that the first stud 172, the conductive post 171, and the first screw 174 form an electrical path to supply power while connecting the ionization module 13 and the power supply main board 15 into a whole, and the structure is compact. In this embodiment, a rechargeable battery is further installed in the water-proof cavity 101, the wireless power receiving module 16 is installed at the bottom of the water-proof cavity 101, the wireless power receiving module 16 is electrically connected with the rechargeable battery, the rechargeable battery is electrically connected with the first stud 172 through an electric wire, and the first screw 174 is connected with the electrode plate 18 through an electric wire, so that power supply to the electrode plate 18 is achieved.

In this embodiment, a separation seal ring 176 is further disposed between the spacer 14 and the bottom cover 12, and the separation seal ring 176 is used to seal the gap between the spacer 14 and the bottom cover 12, so as to prevent water from entering the water-proof cavity 101 from the gap between the spacer 14 and the bottom cover 12.

Further, the electrode sheet 18 includes a power receiving portion 183 and an ionization portion 181, the power receiving portion 183 and the ionization portion 181 are arranged in a non-parallel manner, and the power receiving portion 183 and the ionization portion 181 are connected as one body through a torsion portion 182. The electrode plate 18 has the advantages that the current-passing area of the current-receiving part 183 and the ionization part 181 is increased and the resistance is reduced by integrally forming the current-receiving part 183 and the ionization part 181 through the twisting part 182, and meanwhile, the current-receiving part 183 and the ionization part 181 can be simultaneously assembled during assembly, so that the installation is convenient.

Further, the power receiving portion 183 and the ionization portion 181 are perpendicular to each other. The power receiving portion 183 and the ionization portion 181 arranged perpendicularly to each other are more in accordance with a general electrode tab 18 and power receiving tab structure, and the electrode tab 18 is easy to replace various electrode tabs 18 in the prior art.

Further, the area of the junction between the twisted portion 182 and the ionization portion 181 is 3 times or more the thickness of the ionization portion 181. The area of the junction between the twisted portion 182 and the power receiving portion 183 is 3 times or more the thickness of the ionization portion 181. The width of the twisted portion 182 may be reduced appropriately in order to increase the yield during processing, but the thickness of the twisted portion 182 should be 3 times or more the thickness of the ionized portion 181 after the thickness of the twisted portion 182 is reduced, so as to ensure a good current passing capability and reduce the resistance. Similarly, when the thickness of the twisted portion 182 is reduced, the thickness should be ensured to be 3 times or more that of the ionized portion 181.

Further, the ionization portion 181, the torsion portion 182, and the power receiving portion 183 are integrally press-formed. In the present embodiment, the thickness of the ionization portion 181, the torsion portion 182 and the power receiving portion 183 are the same, and the three portions are formed by integral stamping, which has the advantage of convenient processing.

Further, the ionization module 13 further includes an upper cover 191 and a lower cover 192, the number of the electrode plates 18 is two, and the two electrode plates 18 are disposed between the upper cover 191 and the lower cover 192. The ionization module 13 is designed to be in a structure that the upper cover 191 and the lower cover 192 cover the electrode slice 18, so that the ionization module 13 can be conveniently used in various fruit and vegetable machines, and the universality of the ionization module 13 is improved.

Further, the two electrode plates 18 are respectively a positive electrode plate 18a and a negative electrode plate 18b, the positive electrode plate 18a and the negative electrode plate 18b are different in relative positions of the power receiving portion 183 and the ionization portion 181, a positive electrode positioning groove 1921 and a negative electrode positioning groove 1922 are respectively provided on two sides of the lower cover 192, the positive electrode plate 18a is located in the positive electrode positioning groove 1921, and the negative electrode plate 18b is located in the negative electrode positioning groove 1922. The two electrode plates 18 are divided into the positive electrode plate 18a and the negative electrode plate 18b, so that space is reasonably utilized, and meanwhile, fool-proof design is carried out by means of the positive electrode positioning groove 1921 and the negative electrode positioning groove 1922, so that the positive electrode plate 18a and the negative electrode plate 18b are correctly installed. In this embodiment, the positive positioning groove 1921 and the negative positioning groove 1922 are used to position the ionization portion 181 of the positive electrode sheet 18a and the ionization portion 181 of the negative electrode sheet 18b, respectively. Correspondingly, two groups of electric paths are designed, and the two groups of electric paths respectively communicate the positive electrode plate 18a and the negative electrode plate 18b to the rechargeable battery.

Further, the upper cover 191 is further provided with a positive electrode identifier 1911 and a negative electrode identifier 1912. The lower sealing cover is respectively provided with a positive electrode identifier 1911 and a negative electrode identifier 1912, so that the probability of misloading can be effectively reduced when the power connection piece connected with the first power supply module is accessed.

While the preferred embodiment of the present utility model has been described in detail, the utility model is not limited to the embodiments, and various equivalent modifications and substitutions can be made by those skilled in the art without departing from the spirit of the utility model, and these equivalent modifications and substitutions are intended to be included in the scope of the utility model as defined in the appended claims.

Claims (10)

1. Wireless double-end food material cleaning machine, its characterized in that: comprising the following steps:

the charging device comprises a charging base (2), wherein a first positioning groove is formed in the charging base (2), a wireless power supply module (22) is arranged on the lower side of the first positioning groove, and the wireless power supply module (22) is magnetic;

the cleaning assembly (1) comprises a wireless power receiving module (16), when the cleaning assembly (1) is placed in a first positioning groove, the wireless power supply module (22) and the wireless power receiving module (16) are connected and supply power, and the cleaning assembly (1) and the charging base (2) are magnetically attracted together.

2. The wireless double-ended food material washing machine of claim 1, wherein: still be equipped with electric storehouse (21) in charging base (2), be equipped with the mouth of changing electricity that communicates to the external world on charging base (2), change electric mouthful department and be connected with the storehouse lid detachably, electric storehouse (21) are used for placing for wireless power module (22) power supply's battery.

3. The wireless double-ended food material washing machine of claim 1, wherein: the cleaning assembly (1) comprises a top cover (11), a bottom cover (12), an ionization module (13), a separation piece (14) and a power supply main board (15), wherein the top cover (11) and the bottom cover (12) are connected to form an installation cavity, the separation piece (14) is arranged in the installation cavity, the separation piece (14) is connected with the bottom cover (12) and separates the installation cavity into a water through cavity (102) and a water isolation cavity (101) which are isolated from each other, the power supply main board (15) is arranged in the water isolation cavity (101) and is connected with the separation piece (14), a conductive column (171) is arranged on the power supply main board (15), a first stud (172) is arranged on the lower side of the conductive column (171), a first screw hole is arranged on the upper portion of the conductive column (171), the first stud (172) penetrates through the power supply main board (15) to downwards stretch out and is connected with a first nut (173), the first nut (173) locks the conductive column (171) on the top surface of the power supply main board (15), the first stud (172), the first conductive column (171) and the first screw (174) are sequentially provided with a through hole (13) in the power supply main board (13), the first screw (174) is in threaded connection with the first screw hole, and a waterproof sealing ring (175) is arranged between the head of the first screw (174) and the top surface of the through hole.

4. A wireless double-ended food material washing machine as defined in claim 3, wherein: the electrode plate (18) comprises an electricity connection part (183) and an ionization part (181), wherein the electricity connection part (183) and the ionization part (181) are arranged in a non-parallel manner, and the electricity connection part (183) and the ionization part (181) are connected into a whole through a twisting part (182).

5. The wireless double-ended food material washing machine of claim 4, wherein: the power receiving part (183) and the ionization part (181) are perpendicular to each other.

6. The wireless double-ended food material washing machine of claim 4, wherein: the area of the connection part of the twisting part (182) and the ionization part (181) is more than 3 times of the thickness of the ionization part (181).

7. The wireless double-ended food material washing machine of claim 4, wherein: the area of the connection part of the twisting part (182) and the power receiving part (183) is more than 3 times of the thickness of the ionization part (181).

8. The wireless double-ended food material washing machine of claim 4, wherein: the ionization module (13) further comprises an upper cover (191) and a lower cover (192), the number of the electrode plates (18) is two, and the two electrode plates (18) are arranged between the upper cover (191) and the lower cover (192).

9. The wireless double-ended food material washing machine of claim 8, wherein: the two electrode plates (18) are respectively a positive electrode plate (18 a) and a negative electrode plate (18 b), the positive electrode plate (18 a) and the negative electrode plate (18 b) are different in relative positions of a power connection part (183) and an ionization part (181), a positive electrode positioning groove (1921) and a negative electrode positioning groove (1922) are respectively formed in two sides of the lower cover (192), the positive electrode plate (18 a) is located in the positive electrode positioning groove (1921), and the negative electrode plate (18 b) is located in the negative electrode positioning groove (1922).

10. The wireless double-ended food material washing machine of claim 9, wherein: the upper cover (191) is also provided with a positive electrode mark (1911) and a negative electrode mark (1912).

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