CN215440707U - Electricity-saving structure in zinc electrodeposition process - Google Patents

Abstract

The utility model discloses an electricity-saving structure in a zinc electrodeposition process, and relates to the technical field of metallurgy related tools. The power saver comprises a power saver and a mounting assembly, wherein the back of the power saver is fixedly connected with the mounting assembly, the mounting assembly comprises a first fixing plate and a second fixing plate, and the first fixing plate is fixedly connected to one side of the upper surface of the second fixing plate; the middle part of one end of the upper surface of the electricity-saving device is embedded and connected with a functional button, and the middle part of one side of the top end of the electricity-saving device is connected with a negative ion carbon brush head in an inserting way. The utility model solves the problems that the existing electricity-saving structure is usually difficult to fix and has poor fall-proof performance when in use, thereby causing inconvenient use and easy fall-out through arranging the mounting component, the functional button and the anion carbon brush head; the existing power-saving structure is generally single in function, can only be used for saving power, cannot purify air and has certain limitation.

Description

Electricity-saving structure in zinc electrodeposition process

Technical Field

The utility model belongs to the technical field of metallurgy related tools, and particularly relates to an electricity-saving structure in a zinc electrodeposition process.

Background

The zinc electrodeposition refers to a metallurgical process of extracting zinc by electrolysis by taking zinc sulfate aqueous solution as electrolyte, also called zinc electrolysis, and a power saving structure is usually used in the zinc electrodeposition process, so that the power is saved more, and the power saver is an effective power saving structure, but the zinc electrodeposition still has the following defects in actual use:

1. when the existing power-saving structure is used, the existing power-saving structure is usually difficult to fix, and the falling resistance is poor, so that the existing power-saving structure is inconvenient to use and easy to break;

2. the existing power-saving structure is generally single in function, can only be used for saving power, cannot purify air and has certain limitation.

Therefore, the existing electricity-saving structure in the zinc electrodeposition process cannot meet the requirements in practical use, so that an improved technology is urgently needed in the market to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an electricity-saving structure in a zinc electrodeposition process, which solves the problems that the existing electricity-saving structure is usually difficult to fix and has poor fall resistance so as to cause inconvenient use and easy fall when in use by arranging a mounting component, a functional button and an anion carbon brush head; the existing power-saving structure is generally single in function, can only be used for saving power, cannot purify air and has certain limitation.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to a power-saving structure in a zinc electrodeposition process, which comprises a power saver and a mounting component, wherein the back surface of the power saver is fixedly connected with the mounting component, the mounting component comprises a first fixing plate and a second fixing plate, the first fixing plate is fixedly connected to one side of the upper surface of the second fixing plate, a plurality of second through holes are uniformly formed in the upper surface of the second fixing plate, and second screws are in threaded connection with the rear ends of the bottom surface of the second fixing plate;

the middle part of one end of the upper surface of the electricity-saving device is embedded and connected with a functional button, and the middle part of one side of the top end of the electricity-saving device is connected with a negative ion carbon brush head in an inserting way.

Furthermore, the electricity-saving appliance comprises a main shell and a side shell, the side shell is tightly connected to one side of the main shell, four corners of the side shell are in threaded connection with first screws, the main shell is used for accommodating objects such as a circuit board in the electricity-saving appliance, and the electricity-saving appliance is convenient to disassemble and assemble due to the side shell and the first screws.

Further, the bottom surface of the main shell is uniformly provided with a plurality of heat dissipation holes, the middle part of the upper end of the main shell is provided with a second port, the middle part of one side of the upper end of the main shell is provided with a first port, the middle part of the other side of the upper end of the main shell is provided with a third port, the heat dissipation holes are arranged, the electricity-saving appliance is convenient to dissipate heat, the first port is arranged, the electricity-saving appliance is used for inserting the head of the negative ion toothbrush, the second port is arranged, the fuse is inserted, and the third port is arranged and used for inserting the power plug.

Further, the other end of the upper surface of the main shell is connected with a display screen in an embedded mode, the upper surface of the main shell is located above the function buttons and is connected with a plurality of operation buttons in an embedded mode, the number of the operation buttons is five, the display screen is arranged for displaying related data, and the operation buttons are arranged for completing related operations on the power saver.

Furthermore, the main casing upper end middle part is pegged graft and is connected with the fuse, and main casing upper end opposite side middle part is pegged graft and is connected with the interface, fixed surface is connected with power plug on the interface, main casing opposite side middle part is inlayed and is connected with the switch, by the fuse that sets up for prevent its short circuit, by the interface that sets up, be used for inserting power connector, by the switch that sets up, be used for controlling the start-up and the closing of electricity-saving appliance.

Further, first through-hole evenly is provided with on one side of first fixed plate surface, and first through-hole quantity is three, by the first through-hole that sets up for insert the nail, thereby fix the electricity-saving appliance on the wall.

The utility model has the following beneficial effects:

1. the power-saving device is provided with the mounting component, so that the power-saving device is convenient to mount and prevent from falling, the problems that the conventional power-saving structure is difficult to fix and has poor falling resistance, so that the power-saving device is inconvenient to use and easy to break are solved, the mounting component is fixedly connected to the back of the power-saving device, and therefore, when the power-saving device is mounted, only a nail is required to be inserted into the first through hole and then nailed on a wall surface close to the socket, and meanwhile, the mounting component protects the power-saving device to a certain extent, so that the power-saving device is difficult to break when the power-saving device falls on the ground.

2. When the power saver is used, firstly, a power plug of the power saver is plugged into a socket to be powered on, then a switch is pressed to turn on the power saver, then, the function button is pressed to turn on the function of purifying the air, and related circuit boards and systems in the power saver can control the negative ion carbon brush head to work, so that the effect of purifying the air is achieved under the action of the negative ion carbon brush head.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic top perspective view of the present invention;

FIG. 3 is a schematic diagram of a part of the structure of the power saver of the present invention;

fig. 4 is a schematic structural view of the mounting assembly of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a power saver; 101. a main housing; 1011. heat dissipation holes; 1012. a first port; 1013. a second port; 1014. a third port; 102. a side casing; 103. a display screen; 104. a function button; 105. an operation button; 106. a negative ion carbon brush head; 107. a fuse; 108. an interface; 109. a power plug; 110. a switch; 2. a first screw; 3. a second screw; 4. mounting the component; 401. a first fixing plate; 4011. a first through hole; 402. a second fixing plate; 4021. a second via.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-4, the utility model relates to a power saving structure in a zinc electrodeposition process, which comprises a power saver 1 and a mounting assembly 4, wherein the back of the power saver 1 is fixedly connected with the mounting assembly 4, the mounting assembly 4 comprises a first fixing plate 401 and a second fixing plate 402, the first fixing plate 401 is fixedly connected to one side of the upper surface of the second fixing plate 402, the upper surface of the second fixing plate 402 is uniformly provided with a plurality of second through holes 4021, and the rear two ends of the bottom surface of the second fixing plate 402 are in threaded connection with second screws 3;

the middle part of one end of the upper surface of the electricity-saving appliance 1 is embedded and connected with a functional button 104, the middle part of one side of the top end of the electricity-saving appliance 1 is connected with an anion carbon brush head 106 in an inserting manner, and the mounting component 4 is fixedly connected to the back surface of the electricity-saving appliance 1, so that when the electricity-saving appliance 1 is mounted, only nails are required to be inserted into the first through holes 4011 and then are nailed on the wall surface close to the socket, meanwhile, the mounting component 4 protects the electricity-saving appliance 1 to a certain extent, and the electricity-saving appliance is not easy to break when falling on the ground;

when the electricity-saving appliance 1 is used, firstly, the power plug 109 of the electricity-saving appliance 1 is plugged into a socket to be connected with a power supply, then the switch 110 is pressed to turn on the electricity-saving appliance 1, secondly, the function button 104 is pressed to turn on the function of purifying air, and related circuit boards and systems in the electricity-saving appliance 1 can control the negative ion carbon brush head 106 to work, so that the function of purifying air is achieved under the action of the negative ion carbon brush head 106.

As shown in fig. 1-3, the power saver 1 comprises a main casing 101 and a side casing 102, the side casing 102 is fastened and connected to one side of the main casing 101, four corners of the side casing 102 are in threaded connection with first screws 2, the side casing 101 is arranged and used for accommodating objects such as a circuit board and the like inside the power saver 1, the power saver 1 is convenient to disassemble and assemble through the side casing 102 and the first screws 2, and the main casing 101 and the side casing 102 can be fastened and connected by screwing the first screws 2 clockwise;

a plurality of heat radiation holes 1011 are uniformly formed in the bottom surface of the main casing 101, a second through hole 1013 is formed in the middle of the upper end of the main casing 101, a first through hole 1012 is formed in the middle of one side of the upper end of the main casing 101, a third through hole 1014 is formed in the middle of the other side of the upper end of the main casing 101, the electricity saver 1 can be used for heat radiation through the arranged heat radiation holes 1011, the negative ion carbon brush head 106 can be inserted through the arranged first through hole 1012, the fuse 107 can be conveniently inserted through the arrangement of the second through hole 1013, and the power plug 109 can be inserted through the arranged third through hole 1014;

the other end of the upper surface of the main shell 101 is connected with a display screen 103 in an embedded manner, the upper surface of the main shell 101 is connected with a plurality of operating buttons 105 in an embedded manner above the functional buttons 104, the number of the operating buttons 105 is five, the related data are displayed through the arranged display screen 103, and the power saver 1 can be operated in a related manner by pressing the corresponding operating buttons 105;

the fuse 107 is connected in the middle of the upper end of the main shell 101 in an inserting manner, the interface 108 is connected in the middle of the other side of the upper end of the main shell 101 in an inserting manner, the power plug 109 is fixedly connected to the upper surface of the interface 108, the switch 110 is connected in the middle of the other side of the main shell 101 in an inserting manner, the fuse 107 is arranged, circuit short circuit is prevented, the interface 108 is arranged, the power plug 109 is inserted, and the switch 110 is arranged for controlling the electricity saver 1 to be started and closed.

Wherein as shown in fig. 4, first fixed plate 401 surface one side evenly is provided with first through-hole 4011, and first through-hole 4011 is three in quantity, through first through-hole 4011 who sets up for insert the nail, thereby fix electricity-saving appliance 1 on the wall, use the hammer to beat the nail into the wall in, can fix electricity-saving appliance 1.

The above are only preferred embodiments of the present invention, and the present invention is not limited thereto, and any modification, equivalent replacement, and improvement made to the technical solutions described in the above embodiments, and to some of the technical features thereof, are included in the scope of the present invention.

Claims (6)

1. The utility model provides a structure of economizing on electricity in zinc electrodeposition in-process, includes electricity-saving appliance (1) and installation component (4), its characterized in that: the back surface of the electricity saver (1) is fixedly connected with a mounting assembly (4), the mounting assembly (4) comprises a first fixing plate (401) and a second fixing plate (402), the first fixing plate (401) is fixedly connected to one side of the upper surface of the second fixing plate (402), a plurality of second through holes (4021) are uniformly formed in the upper surface of the second fixing plate (402), and second screws (3) are in threaded connection with the two rear ends of the bottom surface of the second fixing plate (402);

the middle part of one end of the upper surface of the electricity-saving device (1) is embedded and connected with a function button (104), and the middle part of one side of the top end of the electricity-saving device (1) is connected with an anion carbon brush head (106) in an inserting way.

2. The power-saving structure in the zinc electrodeposition process according to claim 1, wherein the power saver (1) comprises a main casing (101) and a side casing (102), the side casing (102) is tightly connected to one side of the main casing (101), and the first screw (2) is screwed at the four corners of the side casing (102).

3. The power-saving structure in the zinc electrodeposition process according to claim 2, wherein the bottom surface of the main casing (101) is uniformly provided with a plurality of heat dissipation holes (1011), the middle of the upper end of the main casing (101) is provided with a second through hole (1013), the middle of one side of the upper end of the main casing (101) is provided with a first through hole (1012), and the middle of the other side is provided with a third through hole (1014).

4. The power-saving structure in the zinc electrodeposition process according to claim 2, wherein the other end of the upper surface of the main casing (101) is connected with a display screen (103) in an embedded manner, the upper surface of the main casing (101) is connected with a plurality of operating buttons (105) in an embedded manner above the functional buttons (104), and the number of the operating buttons (105) is five.

5. The power saving structure in the zinc electrodeposition process according to claim 2, wherein a fuse (107) is inserted and connected in the middle of the upper end of the main shell (101), an interface (108) is inserted and connected in the middle of the other side of the upper end of the main shell (101), a power plug (109) is fixedly connected to the upper surface of the interface (108), and a switch (110) is inserted and connected in the middle of the other side of the main shell (101).

6. The electricity-saving structure in the zinc electrodeposition process according to claim 1, wherein one side of the surface of the first fixing plate (401) is uniformly provided with three first through holes (4011), and the number of the first through holes (4011) is three.

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