CN210480902U

CN210480902U - Water purifying device

Info

Publication number: CN210480902U
Application number: CN201921044779.1U
Authority: CN
Inventors: 刘果; 刘小菡
Original assignee: Suqian Hanshu Environmental Protection Equipment Co ltd
Current assignee: Suqian Hanshu Environmental Protection Equipment Co ltd
Priority date: 2019-07-05
Filing date: 2019-07-05
Publication date: 2020-05-08
Anticipated expiration: 2029-07-05

Abstract

The utility model discloses a water purifying device, include: a first container; a second container for receiving water flowing out of the first container; the second container is detachably connected with the first container through the connecting mechanism, when the second container is connected with the first container, the connecting mechanism enables the water outlet of the first container to be communicated with the water inlet of the second container, and when the second container is separated from the first container, the water outlet of the first container and the water inlet of the second container are sealed through the connecting mechanism.

Description

Water purifying device

Technical Field

The utility model relates to a water purification technology field especially relates to a water purifying device.

Background

The prior art water purification devices comprise only one container for water (which container has a water outlet member such as a tap).

The water purifying device in the prior art has the following defects:

1. when water is used, the water cup needs to be placed below the water faucet to receive water, and the water receiving process consumes time.

2. If the volume of the container on the water purifying apparatus is set to be large, it is not easy to move, and if the volume of the container is set to be small, it is impossible to contain a sufficient amount of water.

SUMMERY OF THE UTILITY MODEL

To the above-mentioned technical problem that exists among the prior art, the embodiment of the utility model provides a water purification unit.

For solving the technical problem, the embodiment of the utility model adopts the following technical scheme:

a water purification apparatus comprising:

a first container;

a second container for receiving water flowing out of the first container;

the second container is detachably connected with the first container through the connecting mechanism, when the second container is connected with the first container, the connecting mechanism enables the water outlet of the first container to be communicated with the water inlet of the second container, and when the second container is separated from the first container, the water outlet of the first container and the water inlet of the second container are sealed through the connecting mechanism.

Preferably, the connection mechanism includes:

a base, in which a flow guide channel is arranged; the first container is arranged on the base, and a water outlet of the first container is communicated with a water inlet port of the flow guide channel; the second container is detachably placed on the base;

a valve mechanism configured to: when the second container is placed on the base, the valve mechanism is used for enabling the water outlet port of the flow guide channel to be communicated with the water inlet of the second container; and when the second container is separated from the base, the valve mechanism is used for enabling the water outlet port and the water inlet of the second container to be closed.

Preferably, the valve mechanism comprises a first valve assembly disposed on the base and a second valve assembly disposed on the second container; wherein:

the first valve assembly includes:

the valve sleeve is arranged in a guide cavity formed in the base and can move along the guide cavity, a first valve cavity is formed in the valve sleeve and is communicated with the water outlet port, the upper end of the valve sleeve protrudes out of the base, and a valve port is formed at the upper end of the valve sleeve;

the valve rod is arranged in the valve sleeve, and the upper end of the valve rod is provided with a plugging core for closing the valve port;

a first spring for pushing the valve housing upward to allow the valve housing to be reset after the downward pressure is released; wherein:

after the valve sleeve moves downwards, the plugging core removes the plugging of the valve port so as to open the valve port.

The second valve assembly includes:

the second valve cavity is formed at the bottom of the second container, and a water inlet of the second container is communicated with the second valve cavity;

a spool disposed in the second valve chamber and slidable along the second valve chamber;

a second spring for urging the spool; wherein:

after the second container is placed on the base, the bottom of the second container presses the valve sleeve to move downwards so that the valve port is opened; the plugging core pushes the valve core to move upwards so as to open the water inlet;

after the second container is removed from the base, the first spring is reset to enable the valve sleeve to move upwards to enable the plugging core to plug the valve port, and the second spring is reset to enable the valve core to move downwards to plug the water inlet.

Preferably, the bottom of the second container forms a jack, the bottom of the jack forms a taper hole, and the upper end of the valve sleeve forms a taper surface; when the second container is placed on the base, the conical surface at the upper end of the valve sleeve is attached and tightly fitted with the hole wall of the conical hole.

Preferably, the conical surface is tightly fit with the conical hole before the plugging core pushes against the valve core to open.

Preferably, a spring ball-ejecting mechanism is arranged between the inner cavity wall of the guide cavity and the valve sleeve; wherein:

when the pressure applied to the valve sleeve is smaller than the preset pressure, the spring ball-ejecting mechanism enables the valve sleeve to be kept at the position; and when the pressure applied to the valve sleeve is greater than the preset pressure, the spring ball ejecting mechanism avoids the valve sleeve, and the valve sleeve moves downwards.

Preferably, the guide cavity is a cylindrical stepped cavity with a small upper part and a large lower part; the valve sleeve is a columnar stepped sleeve, so that the moving stroke of the valve sleeve is limited by a guide cavity to prevent the valve sleeve from being separated from the guide cavity.

Preferably, a stop disc is arranged at the bottom of the valve rod, a third spring is sleeved on the valve rod, and two ends of the third spring respectively abut against the stop disc and the valve sleeve so as to push the valve rod downwards to enable the plugging core to close the valve port.

Preferably, a convex column is arranged at the bottom of the guide cavity below the stop disc to push the stop disc preferentially.

Preferably, a plurality of comb flow plates are circumferentially arranged at the upper part of the first valve cavity in the valve sleeve, and an overflowing channel is formed between every two adjacent comb flow plates.

Preferably, the hole wall of the jack is provided with a first sealing element.

Preferably, a second sealing member is provided at a step of the guide chamber.

Preferably, a through hole is formed in the stepped surface of the valve sleeve so that part of the guide cavity above the stepped surface is communicated with the first valve cavity in the valve sleeve.

Preferably, a water guide opening is formed in the wall of the lower portion of the valve housing so as to enable the water outlet port to be communicated with the first valve cavity.

Preferably, a flow distribution plate is arranged at the joint of the second valve cavity and the water inlet.

Preferably, a first liquid filling channel is formed in a water inlet in the bottom of the second container, and the first liquid filling channel extends to the middle of the second container or below the middle of the second container along the wall of the second container.

Preferably, the second container is provided with a container handle, and a second liquid filling channel is arranged from a water inlet at the bottom of the second container, so that the second liquid filling channel extends along the container handle to the upper part of the second container.

Compared with the prior art, the utility model discloses a purifier's beneficial effect is:

1. the volume of the first container can be allowed to be smaller than the volume of the container in the water purifying device in the prior art, so that when the water purifying device needs to be moved, the second container can be removed in advance and only relevant parts including the first container are moved, and thus, the movement is convenient because the volume of the first container is small (although the volume of the first container is relatively small, the sum volume of the first container and the second container is at least not smaller than the volume of the container in the prior art because the second container has a constant volume, and therefore, the total storage amount of water cannot be reduced because the volume in the first container is reduced).

2. The connecting mechanism leads the second container kept on the connecting mechanism to be always communicated with the first container, so that a certain amount of water is always contained in the second container before the second container is taken, and the second container can be taken and used at any time.

Drawings

Fig. 1 is a schematic structural diagram of a connection mechanism in a water purification apparatus according to an embodiment of the present invention (the second container is in a placement state).

Fig. 2 is a schematic structural diagram (a state where the second container is removed) of a connection mechanism in a water purification apparatus according to an embodiment of the present invention.

Fig. 3 is a front view of a valve sleeve of a water purifying device according to an embodiment of the present invention.

Fig. 4 is a left side view of a valve sleeve in a water purifying device according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a water purifying device according to an embodiment of the present invention.

In the figure:

10-a first valve assembly; 11-a valve housing; 111-a first valve chamber; 112-valve port; 113-a conical surface; 114-a water guide port; 115-a comb plate; 116-a via; 12-a valve stem; 121-plugging core; 13-a first spring; 14-a third spring; 15-a stop disk; 20-a second valve assembly; 21-a valve core; 22-a second valve chamber; 23-a baffle; 24-a second spring; 40-a second container; 41-bottom; 411-a water inlet; 412-a water injection channel; 50-a base; 51-a flow guide channel; 52-water outlet port; 53-convex column; 61-a spring; 62-top bead; 63-annular recess; 71-a first seal; 72-a second seal; 80-first container.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be described in detail with reference to the accompanying drawings and the detailed description.

As shown in fig. 1 to 5, an embodiment of the present invention discloses a water purifying apparatus, which includes a first container 80, a second container 40 and a connecting mechanism.

The first container 80 may be used only for holding water, or may be configured to be able to purify water, for example, purification of water such as tap water may be performed by providing a filter mechanism in the first container 80.

The second container 40 is used to take water from the first container 80.

As will be readily understood: the first container 80 has a water outlet, the second container 40 has a water inlet 411, and the water in the first container 80 can be taken out from the water outlet and can flow in through the water inlet 411.

In some preferred embodiments, the water is caused to flow by gravity, and in other preferred embodiments, the water is caused to flow by external power. The utility model discloses do not restrict the mode that impels rivers to flow.

The connection mechanism is configured to function as follows:

the second container 40 is detachably connected to the first container 80 by the connection mechanism, and when the second container 40 is connected to the first container 80, the connection mechanism connects the water outlet of the first container 80 to the water inlet 411 of the second container 40, and when the second container 40 is separated from the first container 80, the connection mechanism seals both the water outlet of the first container 80 and the water inlet 411 of the second container 40.

The working principle of the water purifying device is as follows:

when the water is not needed to be used, as shown in fig. 1, the second container 40 is held on the connecting mechanism, and at this time, the connecting mechanism holds the second container 40 thereon, so that the water outlet of the first container 80 and the water inlet 411 of the second container 40 are in a conducting state, and the water in the second container 40 always keeps a certain amount.

When water is needed to be used, the second container 40 is directly taken down from the connecting mechanism for use, and in the whole process, the connecting mechanism enables the water outlet of the first container 80 and the water inlet 411 of the second container 40 to be closed, so that the water in the first container 80 cannot leak, and the water in the second container 40 cannot leak.

The advantages of the above embodiment are:

1. the volume of the first container 80 may be allowed to be set smaller than the volume of the container in the water purifying apparatus of the related art, and thus, when the water purifying apparatus needs to be moved, the second container 40 may be removed in advance and only relevant components including the first container 80 may be moved, so that the movement is facilitated due to the small volume of the first container 80 (although the volume of the first container 80 is relatively small, the sum volume of the first container 80 and the second container 40 is at least not smaller than the volume of the container in the related art due to the certain volume of the second container 40, and thus, the total amount of water stored is not reduced due to the small volume of the first container 80).

2. The connecting mechanism leads the second container 40 and the first container 80 which are kept on the connecting mechanism to be always communicated, so that a certain amount of water is always contained in the second container 40 before the second container 40 is taken out, and the second container 40 can be taken out and used at any time.

In a preferred embodiment of the present invention, the connection mechanism is comprised of a base 50 and a valve mechanism. The first container 80 is disposed on the base 50 and the second container 40 is detachably disposed on the base 50 from the base 50, which allows the second container 40 to be held on the connection mechanism by gravity.

Specifically, a flow guide channel 51 is formed in the base 50, and a water inlet port of the flow guide channel 51 penetrates to a water outlet of the first container 80; the valve mechanism is configured to: when the second container 40 is placed on the base 50, the valve mechanism is used for communicating the water outlet 52 of the diversion channel 51 with the water inlet 411 of the second container 40, so that the water in the first container 80 enters the second container 40 through the diversion channel 51; and when the second container 40 is separated from the base 50, the valve mechanism is used to close both the water outlet port 52 and the water inlet 411 of the second container 40, thereby preventing the water of the second container 40 from flowing out of the water outlet port 52 and preventing the water in the second container 40 from flowing out of the water inlet 411.

In a preferred embodiment of the present invention, a valve mechanism of the type described is provided. The valve mechanism includes a first valve assembly 10 and a second valve assembly 20, and the first valve assembly 10 and the second valve assembly 20 are respectively mounted on the base 50 and the second container 40.

Specifically, the first valve assembly 10 includes: valve housing 11, valve stem 12, and first spring 13. A guide cavity is formed in the base 50, the valve sleeve 11 is arranged in the guide cavity and can slide along the guide cavity, a first valve cavity 111 is formed in the valve sleeve 11, the first valve cavity 111 is communicated with the water outlet end of the flow guide channel 51 through a water guide port 114 formed in the wall of the bottom of the valve sleeve 11, the upper end of the valve sleeve 11 can protrude out of the base 50, and a valve port 112 is formed at the upper end of the valve sleeve 11; the valve rod 12 is arranged in the first valve cavity 111 and can move in the valve cavity, the upper end of the valve rod 12 is provided with a plugging core 121, the plugging core 121 can be made of rubber or silica gel materials, and the plugging core 121 is used for plugging the valve port 112 and can enable the valve port 112 to be opened through relative movement with the valve sleeve 11. A first spring 13 is disposed in the guide chamber for pushing valve housing 11 upward so that valve housing 11 protrudes from base 50, and when valve housing 11 is not pressurized, blocking core 121 blocks valve port 112.

The second valve assembly 20 includes: a second valve chamber 22, a spool 21, and a second spring 24. The second valve chamber 22 is formed from the bottom 41 of the second container 40, and the water inlet 411 of the second container 40 is communicated to the second valve chamber 22; the spool 21 is disposed in the second valve chamber 22 and is slidable along the second valve chamber 22; the second spring 24 is used for pushing the valve core 21 to enable the valve core 21 to block the water inlet 411 of the second container 40. Thus, as shown in fig. 1, after the second container 40 is placed on the base 50, the bottom 41 of the second container 40 presses the valve housing 11 to move downward to open the valve port 112; the plugging core 121 pushes the valve core 21 to move upwards to open the water inlet 411, and the water in the first container 80 passes through the diversion channel 51, the first valve chamber 111 and the second valve chamber 22 and enters the second container 40 through the water inlet 411 of the second container 40; after the second container 40 is removed from the base 50, as shown in fig. 2, the first spring 13 is reset to move the valve housing 11 upward to make the plugging core 121 plug the valve port 112, and the second spring 24 is reset to move the valve core 21 downward to plug the water inlet 411, so that the first container 80 and the second container 40 are both isolated and do not leak water.

In a preferred embodiment of the present invention, the bottom of the second container 40 is formed with a socket, the bottom of the socket is formed with a tapered hole, and the upper end of the valve housing 11 is formed with a tapered surface 113; when the second container 40 is placed on the base 50, the tapered surface 113 of the upper end of the valve housing 11 is closely attached to the wall of the tapered hole. In this embodiment, the tapered hole and the tapered surface 113 are brought into close contact with each other, which is advantageous in positioning the position where the second container 40 is placed, and provides a good sealing effect.

In a preferred embodiment of the present invention, the conical surface 113 is closed to the conical hole before the plugging core 121 pushes against the valve element 21 to open. The advantages of sealing the conical surface 113 and the conical hole before pushing the plugging core 121 against the valve core 21 to open are: before the first container 80 and the second container 40 are conducted, the first valve assembly 10 and the second valve assembly 20 are connected in a sealing manner, so that the phenomenon that water leaks from a connection part (such as a gap between the conical surface 113 and the conical hole) between the base 50 and the first container 80 due to the fact that the first valve assembly 10 is opened at the moment that the second container 40 is placed on the base 50 can be effectively avoided.

There are various structural methods for sealing the tapered surface 113 and the tapered hole before the plugging core 121 pushes the valve element 21 to open. For example, the elastic coefficient of the first spring 13 is set to be large enough so that the valve port 112 of the valve housing 11 is not opened by the contraction amount of the first spring 13 before the tapered surface 113 contacts and seals with the tapered hole.

In a preferred embodiment of the present invention, a spring ball is disposed between the inner cavity wall of the guiding cavity and the valve housing 11, and specifically, a receiving hole can be disposed on the inner wall of the guiding cavity, and the spring 61 and the ball 62 in the spring ball are both disposed in the receiving hole, so that the corresponding position of the valve housing 11 is disposed with an annular recess 63. The top bead portion is located in annular recess 63 to limit movement of valve housing 11 when valve housing 11 is subjected to a pressure less than a predetermined pressure; as shown in fig. 1, only when the pressure applied to valve housing 11 is greater than the predetermined pressure, the spring yields, the top bead withdraws from annular recess 63, and valve housing 11 moves downward to open valve port 112.

It should be noted that the preset pressure is given by the gravity of the second container 40, specifically, the wall of the tapered hole presses the tapered surface 113 of the valve housing 11, and at this time, when the valve housing 11 is subjected to a pressure greater than the preset pressure, the contact force between the tapered hole and the tapered surface 113 corresponding to the pressure will enable the tapered hole to seal with the tapered surface 113. Thus, the purpose of sealing the tapered surface 113 and the tapered hole before the plugging core 121 pushes the valve element 21 to open is achieved.

It should be noted that: this can be achieved by providing a receiving hole in the valve housing 11, a spring ball bearing in the receiving hole of the valve housing 11, and an annular recess 63 in the wall of the guide chamber.

In a preferred embodiment of the present invention, the guiding cavity is a cylindrical stepped cavity with a small upper part and a large lower part; as shown in fig. 4 and 5, valve housing 11 is a cylindrical stepped housing to define a moving stroke of valve housing 11 by a guide chamber to prevent valve housing 11 from being removed from the guide chamber. In the present embodiment, the above-described structure of valve housing 11 and the guide chamber allows valve housing 11 to move by itself with a certain stroke.

In a preferred embodiment of the present invention, a stop disc 15 is disposed at the bottom of the valve rod 12, a third spring 14 is sleeved on the valve rod 12, and two ends of the third spring 14 respectively abut against the stop disc 15 and the valve sleeve 11 for pushing the valve rod 12 downwards to make the plug 121 close the valve port 112; and, the bottom of the guide chamber below the stopping disc 15 is provided with a convex column 53 to push the stopping disc 15 preferentially. When the valve housing 11 starts to move down by the pressure of the second container 40, the valve rod 12 moves down synchronously with the valve housing 11 under the action of the third spring 14; after the tapered hole of the valve sleeve 11 is sealed with the tapered surface 113, the valve sleeve 11 continues to move downward, the lower end of the valve rod 12 contacts the convex column 53, the convex column 53 pushes the valve rod 12 to move upward, so that the blocking core 121 opens the valve port 112, and the first container 80 is connected with the second container 40.

The advantages of the above embodiment are:

1. the third spring 14 enables the blocking core 121 to block the valve port 112 with a certain pretightening force, so that the sealing effect of the blocking core 121 on the valve port 112 is better.

2. The third spring 14 makes the valve port 112 delayed to be opened by the plugging core 121, so that the "the conical surface 113 and the conical hole are closed before the plugging core 121 pushes the valve core 21 to be opened" is easier to realize.

3. When the second container 40 is removed, the third spring 14 is reset in cooperation with the first spring 13, so that the blocking core 121 can close the valve port 112 more quickly, which can effectively avoid the leakage of the first valve assembly 10 at the moment when the second container 40 is removed.

In a preferred embodiment of the present invention, a plurality of comb flow plates 115 are circumferentially disposed on an upper portion of the first valve cavity 111 in the valve housing 11, and an overflow channel is formed between adjacent comb flow plates 115. In this embodiment, the valve rod 12 penetrates through the through hole defined by the plurality of flow deflectors 23, so that the radial play of the valve rod 12 can be effectively limited.

In a preferred embodiment of the present invention, the hole wall of the insertion hole is provided with a first sealing member 71; a second seal 72 is provided at the step of the guide chamber to effect sealing against the corresponding location.

In a preferred embodiment of the present invention, a through hole 116 is formed on the stepped surface of the valve housing 11 so that a portion of the guide chamber above the stepped surface communicates with the first valve chamber 111 in the valve housing 11. In this embodiment, during the downward movement of valve housing 11, the water in first valve chamber 111 enters the part of the pilot chamber above the stepped surface through-hole 116, which is advantageous to reduce the pressure of the water in first valve chamber 111.

In a preferred embodiment of the present invention, a dividing plate is provided at the junction of the second valve chamber 22 and the water inlet 411. In this embodiment, the diverter plate has a certain slowing effect on the flow of water.

In a preferred embodiment of the present invention, the water inlet 411 is communicated with the upper portion of the second container 40 via the water filling channel 412, so that the water passing through the water inlet 411 passes through the water filling channel 412 to enter the second container 40. Specifically, a first liquid injection channel is opened from the water inlet 411 at the bottom of the second container 40, and the first liquid injection channel extends to the middle part or below the middle part of the second container 40 along the container wall of the second container 40; preferably, the second container 40 has a container handle, and a second filling channel opens from the water inlet 411 at the bottom of the second container 40, such that the second filling channel extends along the container handle and to the upper part of the second container 40.

The above embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and the protection scope of the present invention is defined by the claims. Various modifications and equivalents of the invention can be made by those skilled in the art within the spirit and scope of the invention, and such modifications and equivalents should also be considered as falling within the scope of the invention.

Claims

1. A water purification device, characterized by comprising:

a first container;

a second container for receiving water flowing out of the first container;

2. The water purification apparatus of claim 1, wherein the connection mechanism comprises:

3. The water purification apparatus of claim 2, wherein the valve mechanism comprises a first valve assembly disposed on the base and a second valve assembly disposed on the second container; wherein:

the first valve assembly includes:

after the valve sleeve moves downwards, the plugging core releases the plugging of the valve port so as to open the valve port;

the second valve assembly includes:

a second spring for urging the spool; wherein:

4. The water purifying device as claimed in claim 3, wherein the second container has a bottom formed with a socket, the socket having a bottom formed with a tapered hole, and the valve housing having an upper end formed with a tapered surface; when the second container is placed on the base, the conical surface at the upper end of the valve sleeve is attached and tightly fitted with the hole wall of the conical hole.

5. The water purifying device of claim 4, wherein the sealing between the conical surface and the conical hole is performed before the plugging core pushes the valve core to open.

6. The water purification apparatus of claim 5, wherein a spring ball-ejecting mechanism is disposed between the inner chamber wall of the guide chamber and the valve housing; wherein:

7. The water purifying device of claim 3, wherein the guide cavity is a cylindrical stepped cavity with a small upper part and a large lower part; the valve sleeve is a columnar stepped sleeve, so that the moving stroke of the valve sleeve is limited by a guide cavity to prevent the valve sleeve from being separated from the guide cavity.

8. The water purifying device as claimed in any one of claims 3 to 7, wherein a stop disc is disposed at the bottom of the valve rod, a third spring is sleeved on the valve rod, and two ends of the third spring respectively abut against the stop disc and the valve sleeve for pushing the valve rod downwards to make the plugging core close the valve port.

9. The water purifying device of claim 8, wherein the bottom of the guide chamber below the stopping disc is provided with a convex pillar to push the stopping disc preferentially.

10. The water purifying device of claim 3, wherein a plurality of combing flow plates are circumferentially arranged on the upper part of the first valve cavity in the valve sleeve, and an overflowing channel is formed between adjacent combing flow plates.

11. The water purification apparatus of claim 4, wherein the wall of the socket is provided with a first sealing member.

12. The water purification apparatus of claim 7, wherein a second sealing member is provided at a step of the guide chamber.

13. The water purifying device as claimed in claim 7, wherein the stepped surface of the valve housing is formed with a through hole to communicate a portion of the guide chamber above the stepped surface with the first valve chamber in the valve housing.

14. The water purifying device as claimed in claim 3, wherein a water guide opening is opened on a wall of the lower portion of the valve housing to communicate the water outlet port with the first valve chamber.

15. The water purifying device of claim 3, wherein a flow dividing plate is arranged at the joint of the second valve chamber and the water inlet.

16. The water purifying device of claim 3, wherein a first liquid filling channel is opened from the water inlet at the bottom of the second container, and the first liquid filling channel extends to the middle part or below the middle part of the second container along the container wall of the second container.

17. The water purification apparatus of claim 3, wherein the second container has a container handle, and a second filling channel opens from the water inlet at the bottom of the second container such that the second filling channel extends along the container handle and to an upper portion of the second container.