CN209892839U - Mechanical automatic water taking system - Google Patents

Abstract

The utility model discloses a mechanical automatic water taking system, which comprises a frame, wherein the frame comprises a water leading part; the water taking device is characterized in that a mounting cavity is arranged in the machine base, the top of the mounting cavity is provided with an opening, and a tray seat for placing a water taking container is arranged on the opening; the valve body assembly and a plurality of elastic devices are arranged in the mounting cavity; the valve body assembly comprises a valve cover and a valve core, and a plurality of magnet blocks are arranged in the installation cavity; the magnet block and the tray seat are lifted synchronously; a channel is arranged in the valve cover; the valve core is positioned in the channel; a valve opening interval and a valve closing interval are arranged in the channel; an elastic component is also arranged in the channel; the elastic component is positioned between the magnet block and the valve core; one end of the elastic component is connected with the valve core, and the other end of the elastic component is abutted against the closed end of the channel; in the installation cavity, the magnet block is at least provided with a first magnetic area; when the valve core is positioned in the first magnetic area, the valve core moves to a valve opening area. The utility model has the advantages of reduce design and equipment cost, improve user experience and feel, simplify and be convenient for user operation and installation.

Description

Mechanical automatic water taking system

Technical Field

The utility model belongs to the technical field of the water purifier technique and specifically relates to a mechanical type automatic water intaking system is related to.

Background

On the market, automatic water intaking machine lin langdu wherein to the water purifier that has external water cup, the control goes out water mainly has following several modes:

1. manually controlling to open or close the valve; the technology has the disadvantages that manual operation is needed, a user needs to wait for the water receiving process, the operation of the user is inconvenient, and the experience is poor;

2. the valve is automatically opened through infrared induction, when the water is full, the water cup is boiled, and the infrared induction is carried out simultaneously, and the valve is quickly closed; the technology has the disadvantages that the infrared inductor needs to be connected with a control system of the whole machine, the wire length of the inductor is designed and fixed, and the part needs to be moved for a long distance according to own requirements, so that the realization cannot be realized. The design cost of the infrared ray is high, the assembly is more responsible, and the labor cost is high; the water receiving platform can not sense whether water is added to a rated value or not, and a user needs to be kept at the water receiving platform;

3. the valve is automatically opened through infrared induction, and when water is added to the weight designed by the gravity sensor, the valve is automatically closed by the system; if the water with the rated weight is not added, the water cup is removed, and the water valve is automatically closed through the infrared inductor; this technique has a drawback in that it requires a lot of precision instruments, has many parts, and has high design and assembly costs.

Therefore, it is necessary to develop a mechanical automatic water intake system to solve the above technical drawbacks.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a reduce design and equipment cost, improve user experience and feel, simplify and be convenient for the mechanical automatic water intaking system of user operation and installation.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a mechanical automatic water taking system comprises a base, wherein the base comprises a water leading part; the water taking device is characterized in that a mounting cavity is arranged in the base, the top of the mounting cavity is provided with an opening, and a tray seat for placing a water taking container is arranged on the opening; a valve body assembly fixed in the base and a plurality of elastic devices capable of lifting the tray base relative to the base are arranged in the mounting cavity; the valve body assembly comprises a water inlet port, a water outlet port, a valve cover and a valve core made of magnetic materials, wherein the water inlet port and the water outlet port are communicated with each other; the water outlet port is communicated with the water diversion part; a channel is arranged in the valve cover, a valve opening interval and a valve closing interval are formed in the channel, and the valve core moves back and forth between the valve opening interval and the valve closing interval; an elastic component used for adjusting the position of the valve core is further arranged in the channel, and the elastic component is positioned on one side of the valve core, which is far away from the tray seat; the installation cavity is also internally provided with a plurality of magnet blocks for controlling the position of the valve core, and the magnet blocks and the tray seat are lifted synchronously; in the installation cavity, at least a first magnetic area is formed on the magnet block; when the valve core is positioned in the first magnetic area, the valve core moves to a valve opening area, and when the valve core leaves the first magnetic area, the valve core is extruded by an elastic component to move to a valve closing area and cut off the communication between the water inlet port and the water outlet port.

The working principle of the utility model is as follows:

firstly, when the tray seat is positioned in a container without water, the valve core bears the thrust of the elastic component and is positioned in a valve closing interval; closing the valve; the external water source can not supply water to the water diversion part through the valve body assembly; when the water taking container is placed on the tray, the tray seat moves towards the base under the action of gravity, namely the tray seat descends, and the magnet block also descends; at the moment, the valve core is positioned in the first magnetic area and in a valve opening area in the channel; the valve body assembly is opened, the external water source is continuously conveyed to the water leading part, and the water leading part then super-fetching the water container to add water; along with the water increase in the water intaking container, pressure is bigger and bigger, and the tray seat continues to move towards, and the case leaves first magnetic domain, no longer bears the pulling force that first magnetic domain provided, and at this moment, the case lies in the valve and closes the interval under elastic component's thrust effect, and the valve is closed, and external water source can't want diversion portion to supply water through valve body assembly.

Preferably, the water introducing part is vertically arranged; the water diversion part is provided with a water inlet communicated with the valve body assembly; the water diversion part is provided with a water intake above the tray seat, and a space for placing a water intake container is reserved between the water intake and the tray seat.

Preferably, the magnet block includes at least a first magnet block; the first magnet block forms the first magnetic area and is opposite to and attracted with the valve core.

Preferably, the magnet block is further formed with a second magnetic region located below the first magnetic region and a third magnetic region located above and below the first magnetic region; when the valve core is positioned in the second magnetic area, the valve core moves to a valve closing area; and when the valve core is positioned in the third magnetic area, the valve core moves to a valve closing area.

Preferably, the magnet block further includes at least a second magnet block and a third magnet block; the third magnet block and the second magnet block are sequentially arranged from top to bottom along the lifting direction of the tray seat; the second magnet block is formed in the second magnetic area and repels the valve core in the same polarity; the third magnet block is formed in the third magnetic area and repels the valve core in the same polarity.

Preferably, the valve body assembly further comprises a valve base; the water inlet port and the water outlet port are formed in the valve base; a cavity communicated with the water inlet port is formed in the valve base; a first opening facing the valve cover is arranged in the cavity, and the valve cover covers the first opening; a sealing channel communicated with the water outlet port is further arranged in the cavity, and a second opening facing the valve cover is arranged in the sealing channel; the valve cover is provided with a sealing block which can be squeezed and sealed in the second opening by the valve core, one end of the sealing block faces the second opening, and the other end of the sealing block is communicated to the channel.

Preferably, the valve cover is formed with a protrusion extending toward one end of the magnet block, and the channel is formed in the protrusion.

Preferably, the protruding block is designed to be columnar, and the central axis of the protruding block is perpendicular to the lifting axis of the tray seat.

Preferably, the valve core is made of a magnetic metal or a magnetic material.

The utility model has the advantages of reduce design and equipment cost, improve user experience and feel, simplify and be convenient for user operation and installation.

Drawings

Fig. 1 is a schematic structural view of a state of a container without water intake of an automatic water intake machine in embodiment 1 of the present invention;

fig. 2 is a schematic structural view of the automatic water intake machine in embodiment 1 of the present invention showing the water intake container in a water-filling state;

fig. 3 is a schematic structural view of a full water state of a water intake container of the automatic water intake machine in embodiment 1 of the present invention;

fig. 4 is an exploded view of a valve body assembly in embodiment 1 of the present invention;

fig. 5 is a schematic view of a valve base structure of a valve body in embodiment 1 of the present invention;

fig. 6 is a schematic structural view of a water taking machine in embodiment 1 of the present invention;

fig. 7 is a schematic structural view of a water feeding state of a water feeding container of an automatic water feeder according to embodiment 2 of the present invention.

Description of reference numerals: 1-a machine base; 2-a water-introducing part; 3-a water intake container; 4-a tray seat; 5, mounting a cavity; 6-a first spring; 7-a valve body assembly; 71-a valve cover; 711-a protruding block; 72-a valve core; 73-channel; 74-a valve base; 741-a water inlet port; 742-a water outlet port; 743-a cavity; 744-sealing the channel; 745-a first opening; 746 — second opening; 75-a sealing block; 8-mounting the bar; 9-a first magnet block; 10-a second magnet block; 11-a third magnet block; 12-second spring.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

Example 1:

as shown in fig. 1-6, a mounting cavity 5 is arranged in the machine base 1, the top of the mounting cavity 5 is provided with an opening, and a tray seat 4 for placing a water taking container 3 is arranged on the opening; a valve body assembly 7 fixed in the base 1 and 4 elastic devices which can enable the tray base 4 to lift relative to the base 1, namely a first spring 6, are arranged in the mounting cavity 5; the valve body assembly 7 comprises a valve cover 71 and a valve core 72 made of magnetic materials, and a channel 73 for the valve core 72 to reciprocate is arranged in the valve cover 71; a valve opening interval and a valve closing interval are arranged in the channel 73; a magnet block for controlling the valve core 72 to reciprocate between the valve opening interval and the valve closing interval is also arranged in the mounting cavity 5; the magnet block and the tray seat 4 are lifted synchronously; a channel 73 facing the magnet block and having a closed end at the end is arranged in the valve cover 71; also disposed within the passage 73 is a resilient assembly for adjusting the position of the spool 72, namely a second spring 12; the second spring 12 is positioned between the magnet block and the valve core 72; one end of the second spring 12 is connected with the valve core 72, and the other end is abutted against the closed end of the channel 13; in the installation cavity 5, a third magnetic area, a first magnetic area and a second magnetic area are sequentially formed on the magnet block from top to bottom; when the valve core 72 is positioned in the first magnetic area, the valve core 72 moves to a valve opening area; when the valve core 72 is located in the second magnetic area, the valve core 72 moves to a valve-closing area; a third magnetic region above the first magnetic region; when the valve element 72 is located in the third magnetic region, the valve element 72 moves to the third magnetic region of the valve-closed region.

The magnet blocks comprise a first magnet block 9, a second magnet block 10 and a third magnet block 11, and the third magnet block 11, the first magnet block 9 and the second magnet block 10 are sequentially arranged from top to bottom along the lifting direction of the tray seat 4; the first magnet block 9 forms a first magnetic area and is opposite to and attracted with the valve core 72; the second magnet block 10 forms a second magnetic area and repels the valve core 72 with the same polarity; the third magnet 11 is formed in a third magnetic region and repels the valve element 72 with like poles.

Wherein, a mounting bar 8 for mounting the magnet block is arranged in the mounting cavity 5; the mounting bar 8 is arranged along the lifting direction of the tray base and moves synchronously with the tray base 4.

As shown in fig. 4 and 5, the valve body assembly 7 further includes a valve seat 74; the valve base 74 is provided with a water inlet port 741 for communicating with tap water and a water outlet port 742 communicated with the water intake 21 of the water diversion part 2; a cavity 743 is arranged in the valve base 74; a first opening 745 facing the valve cover 71 is arranged in the cavity 743; a sealing passage 744 is also arranged in the cavity 743; a second opening 746 facing the valve cap 71 is provided in the sealing passage 744; the water inlet port 741 is in communication with the water outlet port 742; the water inlet port 741 communicates with the cavity 743; the water outlet port 742 communicates with the sealing passage 744; the valve cover 71 covers the first opening 745 of the valve body seat 74 through screws; a sealing block 75 which can be pressed and sealed on the second opening 746 by the valve core is arranged between the valve cover 71 and the valve body seat 74; the second opening 746 is sealed by the seal block 75, and one end face of the seal block 75 facing the valve cover 71 is in contact with the valve element 72; valve body assembly 7 further includes a valve base 74; the end surface of the valve cover 71 away from the valve base 74 extends towards the mounting strip 8 to form a protruding block 711; the protruding block 711 is in a columnar design, and the central axis of the protruding block 711 is vertical to the lifting axis of the tray seat; the channel 73 is formed in the protruding block 711.

In addition, an extension block for preventing the tray seat 4 from separating from the machine base 1 is formed at the opening of the tray seat 4 and extends outwards; an extension block is formed in the opening of the base 1 and extends towards the inside of the mounting cavity 5; the extension block is connected with the extension block in a clamping mode.

As shown in fig. 1 to 3, the second magnet block 10, the first magnet block 9 and the third magnet block 11 are sequentially arranged along the direction of the base 1 toward the tray base 4; when the water taking container 3 is not arranged on the tray seat 4, the polarity of the valve core 72 is the same as that of the second magnet block 10, the valve core 72 bears the magnetic thrust of the second magnet block 10 and the thrust of the second spring 12, the valve core 72 pushes the sealing block to seal the second opening 746 of the valve base, and tap water cannot be supplied to the water intake part 2 through the valve body assembly 7; when the water taking container 3 is placed on the tray seat 4, the tray seat 4 moves towards the base 1 under the action of gravity of the tray seat 4, at the moment, the valve core 72 is opposite to the first magnet block 9 in polarity, the valve core 72 is attracted by the first magnet block 9, the valve core 72 moves towards the first magnet block 9, the valve core 72 is separated from the sealing block 75, the sealing block 75 is separated from the second opening 746 under the action of water pressure, namely the valve body assembly 7 is opened, and tap water is supplied to the water introducing part 2 through the valve body assembly 7; the tray seat 4 continues to move towards the base 1 under the action of gravity until the valve core 72 is close to the third magnet block 11, at this time, the valve core 72 has the same polarity as the first magnet 9, the valve core 72 bears the magnetic thrust of the third magnet block 11 and the thrust of the second spring 12, the valve core 72 pushes the sealing block 75 to move towards the second opening 746 of the valve base 74, the amount of tap water passing through the valve body assembly 7 is gradually reduced, until the water taking container 3 is in a full water state, the second opening 746 of the valve base 74 is sealed by the sealing block 75, the tap water cannot enter the sealing channel 744 and then enter the water outlet port 742, and therefore the tap water cannot supply water to the water diversion part 2 through the valve body assembly 7.

Example 2:

embodiment 2 differs from embodiment 1 in that, as shown in fig. 7, in embodiment 2, the valve body 72 is located in the first magnetic region formed by the first magnet block 9, and the polarity of the first magnet block 9 and the polarity of the valve body 72 attract each other in an opposite manner.

As shown in fig. 7, when the water intake container 3 is not present on the tray seat 4, the valve core 72 is pressed against the sealing block 76 by the pushing force generated from the second spring 12, so that the second opening 746 of the valve base 74 is pressed, i.e. the valve core 72 seals the second opening 746 of the valve base 74, and the tap water cannot be supplied to the water intake part 2 through the valve body assembly 7; when the water taking container 3 is placed on the tray seat 4, the tray seat 4 moves towards the base 1 under the action of gravity of the tray seat 4, at the moment, the polarity of the valve core 72 is opposite to that of the first magnet block 9, the valve core 72 is attracted by the first magnet block 9, namely, the valve core 72 moves towards the direction of the first magnet block 9, the sealing block 76 is separated from the second opening 746 of the valve base 74, namely, the valve body assembly 7 is opened, and tap water is injected into the water introducing part 2 through the valve body assembly 7; the tray seat 4 continues to move towards the machine seat 1 under the action of gravity until the valve core 72 is separated from the magnetic area of the first magnet block 9, and at the moment, the water taking container 3 is in a full water state; at the same time, the valve core 72 receives the thrust force generated from the second spring 12, the second opening 746 of the valve base 74 is sealed, and the tap water cannot be supplied to the water guide 2 through the valve body assembly 7

While the invention has been described with reference to specific embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or use to the teachings of the invention without departing from its scope. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (10)

1. A mechanical automatic water taking system comprises a base, wherein the base comprises a water leading part; the water taking device is characterized in that a mounting cavity is arranged in the base, the top of the mounting cavity is provided with an opening, and a tray seat for placing a water taking container is arranged on the opening; a valve body assembly fixed in the base and a plurality of elastic devices capable of lifting the tray base relative to the base are arranged in the mounting cavity; the valve body assembly comprises a water inlet port, a water outlet port, a valve cover and a valve core made of magnetic materials, wherein the water inlet port and the water outlet port are communicated with each other; the water outlet port is communicated with the water diversion part; a channel is arranged in the valve cover, a valve opening interval and a valve closing interval are formed in the channel, and the valve core moves back and forth between the valve opening interval and the valve closing interval; an elastic component used for adjusting the position of the valve core is further arranged in the channel, and the elastic component is positioned on one side of the valve core, which is far away from the tray seat; the installation cavity is also internally provided with a plurality of magnet blocks for controlling the position of the valve core, and the magnet blocks and the tray seat are lifted synchronously; in the installation cavity, at least a first magnetic area is formed on the magnet block; when the valve core is positioned in the first magnetic area, the valve core moves to a valve opening area, and when the valve core leaves the first magnetic area, the valve core is extruded by an elastic component to move to a valve closing area and cut off the communication between the water inlet port and the water outlet port.

2. The mechanical automatic water intake system according to claim 1, wherein the water intake part is vertically arranged; the water diversion part is provided with a water inlet communicated with the valve body assembly; the water diversion part is provided with a water intake above the tray seat, and a space for placing a water intake container is reserved between the water intake and the tray seat.

3. The mechanical automatic water intake system according to claim 1, wherein the magnet block comprises at least a first magnet block; the first magnet block forms the first magnetic area and is opposite to and attracted with the valve core.

4. The mechanical automatic water taking system according to claim 3, wherein the magnet block is further formed with a second magnetic region located below the first magnetic region and a third magnetic region located below and above the first magnetic region; when the valve core is positioned in the second magnetic area, the valve core moves to a valve closing area; and when the valve core is positioned in the third magnetic area, the valve core moves to a valve closing area.

5. The mechanical automatic water intake system according to claim 4, wherein the magnet block further comprises at least a second magnet block and a third magnet block; the third magnet block and the second magnet block are sequentially arranged from top to bottom along the lifting direction of the tray seat; the second magnet block is formed in the second magnetic area and repels the valve core in the same polarity; the third magnet block is formed in the third magnetic area and repels the valve core in the same polarity.

6. The mechanical automatic water taking system according to claim 1, wherein a mounting bar for mounting a plurality of the magnet blocks is arranged in the mounting cavity; the mounting bar is arranged along the lifting direction of the tray seat and moves synchronously with the tray seat.

7. The mechanical automatic water intake system of claim 1, wherein the valve body assembly further comprises a valve base; the water inlet port and the water outlet port are formed in the valve base; a cavity communicated with the water inlet port is formed in the valve base; a first opening facing the valve cover is arranged in the cavity, and the valve cover covers the first opening; a sealing channel communicated with the water outlet port is further arranged in the cavity, and a second opening facing the valve cover is arranged in the sealing channel; the valve cover is provided with a sealing block which can be squeezed and sealed in the second opening by the valve core, one end of the sealing block faces the second opening, and the other end of the sealing block is communicated to the channel.

8. The mechanical automatic water intake system according to claim 7, wherein the valve cover is formed with a protruding block extending toward one end of the magnet block, and the passage is formed in the protruding block.

9. The automatic mechanical water intake system according to claim 8, wherein the protruding block is of a cylindrical design, and a central axis of the protruding block is perpendicular to a lifting axis of the tray seat.

10. The mechanical automatic water intake system according to claim 1, wherein the valve core is made of a magnetic material.

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