CN109502155B - Liquid dispenser - Google Patents

Abstract

The invention discloses a liquid dispenser, comprising: a mounting base for connecting to a liquid container; the push-pull valve is arranged on the mounting base, is provided with a push-pull opening and closing structure and is in liquid communication with the liquid container; a rotary input member rotatably held on the mounting base; the movable transmission piece can be held on the mounting base in a linear reciprocating mode and is used for realizing power transmission between the push-pull valve and the rotary input piece so as to drive the push-pull valve to be opened and closed in a push-pull mode, and the force input end of the rotary input piece and the linear reciprocating motion of the movable transmission piece are distributed in a coplanar mode. The liquid distributor can eliminate the bending moment of the external force acting on the rotary input piece, so that the bending fracture risk in the driving process of the rotary input piece is avoided, the structural safety is ensured, and the reliable opening and closing of the liquid container and the smooth output of liquid are realized.

Description

Liquid dispenser

Technical Field

The invention belongs to the technical field of liquid control, and particularly relates to a liquid dispenser.

Background

The liquid container is used for loading the container, and when liquid is needed to be discharged, the liquid outlet valve is needed to be used for opening and closing so as to improve the operation convenience. The existing liquid outlet valve has the defects of complex structure and inconvenient operation. There are also some liquid outlet valves with operation handles, which are limited in structure and are easy to break and fail at the handle ends, so that great potential safety hazards exist in the operation process.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides a liquid dispenser which is used for providing a safe and reliable operation mode, eliminating the bending fracture risk of a rotary input piece and realizing the reliable opening and closing of a liquid container and the smooth output of liquid.

The aim of the invention is achieved by the following technical scheme:

a liquid dispenser comprising:

a mounting base for connecting to a liquid container;

the push-pull valve is arranged on the mounting base, is provided with a push-pull opening and closing structure and is in liquid communication with the liquid container;

a rotary input member rotatably held on the mounting base;

the movable transmission piece can be held on the mounting base in a linear reciprocating mode and is used for realizing power transmission between the push-pull valve and the rotary input piece so as to drive the push-pull valve to be opened and closed in a push-pull mode, and the force input end of the rotary input piece and the linear reciprocating motion of the movable transmission piece are distributed in a coplanar mode.

As an improvement of the above technical solution, the movable transmission member has a first clutch end, and the rotation input member is reciprocally rotated in a circumferential direction to be connected/separated from the first clutch end.

As a further improvement of the above technical solution, the rotary input member includes a driving handle end and a rotation shaft end that are connected to each other, the axial direction of the driving handle end and the linear reciprocating motion of the movable transmission member are distributed in a coplanar manner, and the rotation shaft end is hinged to the mounting base.

As a further improvement of the above technical solution, the mounting base has a circular arc guide portion for realizing the rotation guide of the rotation input member.

As a further improvement of the above technical solution, an elastic element is disposed between the rotary input member and the mounting base, for achieving circumferential return of the rotary input member.

As a further improvement of the technical scheme, the liquid distributor further comprises a sliding seat, wherein two ends of the sliding seat are respectively connected with the movable transmission part and the push-pull valve, and the sliding seat can be held on the mounting base in a linear reciprocating manner to drive the push-pull valve to be opened and closed in a push-pull manner.

As a further improvement of the above technical solution, the movable transmission member has a second clutch end, and the movable transmission member linearly reciprocates to connect/disconnect the second clutch end to/from the sliding seat.

As a further improvement of the above technical solution, the sliding seat has a clutch connection portion for connecting/separating from the second clutch end.

As a further improvement of the above technical solution, the second clutch end has a first clutch wall and a second clutch wall, and the first clutch wall and the second clutch wall are located at two sides of the clutch connection portion along the linear reciprocating direction of the movable transmission member.

As a further improvement of the technical scheme, an elastic element is arranged between the sliding seat and the mounting base, and the elastic element elastically stretches and contracts along the linear reciprocating motion direction of the sliding seat and is used for resetting the sliding seat.

The beneficial effects of the invention are as follows:

the installation base is connected with the liquid container, the movable transmission piece is movably connected with the rotary input piece and the sliding seat, the rotary motion of the rotary input piece is converted into linear reciprocating motion, the push-pull valve is driven to push and pull to open and close so as to realize fluid communication/fluid interruption, the force input end of the rotary input piece and the linear reciprocating motion of the movable transmission piece are distributed in a coplanar mode, the bending moment of the external force acting on the rotary input piece is eliminated, the bending fracture risk of the rotary input piece in the driving process is avoided, the structural safety is ensured, and the reliable opening and closing of the liquid container and the smooth output of liquid are realized.

In order to make the above objects, features and advantages of the present invention more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an isometric view of a liquid dispenser according to embodiment 1 of the present invention;

FIG. 2 is a schematic cross-sectional view of a liquid dispenser according to embodiment 1 of the present invention;

FIG. 3 is an enlarged partial schematic view of the liquid dispenser of FIG. 2;

FIG. 4 is a schematic front view of the liquid dispenser of embodiment 1 of the present invention with the mounting base removed;

FIG. 5 is an enlarged partial schematic view of the liquid dispenser of FIG. 4;

fig. 6 is a schematic partial cross-sectional view of the liquid dispenser of fig. 4.

Description of main reference numerals:

1000-liquid distributor, 1100-mounting base, 1110-bearing rail, 1120-limit part, 1130-circular arc guide part, 1200-push-pull valve, 1210-fluid input end, 1220-valve core, 1230-fluid output end, 1300-rotation input piece, 1310-rotation shaft end, 1320-driving handle end, 1330-turnover clutch part, 1400-movable transmission piece, 1410-first clutch end, 1420-second clutch end, 1421-first clutch wall, 1422-second clutch wall, 1500-sliding seat, 1510-bearing seat body, 1520-clutch connection part and 1600-second elastic element.

Detailed Description

In order to facilitate an understanding of the present invention, the liquid dispenser will be described more fully below with reference to the accompanying drawings. The drawings show preferred embodiments of the liquid dispenser. However, the liquid dispenser may be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

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

Example 1

Referring to fig. 1 to 3 in combination, the present embodiment discloses a liquid dispenser 1000, where the liquid dispenser 1000 includes a mounting base 1100, a push-pull valve 1200, a rotary input member 1300 and a movable transmission member 1400, and is used for providing a safe and reliable operation mode, so as to realize reliable opening and closing of a liquid container and smooth output of liquid.

Wherein the mounting base 1100 is used to connect a liquid container to securely hold the liquid dispenser 1000 to the liquid container to provide a reliable operating basis and form a stable liquid flow path. The liquid container is used for loading liquid, and comprises a barrel body, a tank body, a box body or a beverage machine with a liquid bin and the like.

The push-pull valve 1200 is disposed on the mounting base 1100, and is used for controlling the opening and closing of the fluid output of the liquid container. Specifically, the push-pull valve 1200 has a fluid input end 1210 and a fluid output end 1230, wherein the fluid input end 1210 is in fluid communication with the liquid container to introduce the liquid, and the fluid output end 1230 is used to complete the external output of the liquid.

The push-pull valve 1200 has a push-pull opening and closing structure, and the valve core 1220 is turned on or off by the push-pull movement of the rod end, so that the fluid communication or the fluid interruption between the fluid input end 1210 and the fluid output end 1230 is realized. When the valve cartridge 1220 is turned on, the fluid input 1210 is in fluid communication with the fluid output 1230 to output a liquid; when the valve core 1220 is closed, the fluid input 1210 and the fluid output 1230 are fluidly disconnected to stop the output. Illustratively, the valve cartridge 1220 has a unidirectional conductive property, preventing the reverse flow of the liquid to ensure the unity of the output direction.

The rotary input member 1300 is rotatably held on the mounting base 1100 for inputting rotary motion, providing power required for opening the push-pull valve 1200. Illustratively, the rotary input 1300 includes a rotary shaft end 1310, the rotary shaft end 1310 being hinged to the mounting base 1100 for circumferential reciprocal movement. Illustratively, the linear reciprocating motion of the movable transmission member 1400 is axially perpendicular to the rotational axis (rotational shaft end 1310) of the rotary input member 1300, ensuring efficient motion transfer.

The movable transmission member 1400 is reciprocally held in a linear manner on the mounting base 1100 for effecting power transmission between the push-pull valve 1200 and the rotary input member 1300, and effecting conversion between circular motion and linear motion. In the opening of the liquid outlet stroke, the rotary motion of the rotary input member 1300 is input to the movable transmission member 1400, so that the movable transmission member 1400 moves along the first direction to drive the pull rod end to push and pull, and the valve core 1220 is conducted to enable the fluid input end 1210 to be in fluid communication with the fluid output end 1230, so that the liquid in the liquid container can be output.

The force input end of the rotary input member 1300 and the linear reciprocating motion of the movable transmission member 1400 are distributed in a coplanar manner, so that an external force applied to the rotary input member 1300 by an operator is ensured to be positioned in a motion plane of the movable transmission member 1400, a force arm between the external force and the motion plane of the movable transmission member 1400 is zero, and a bending moment applied to the rotary input member 1300 by the external force is eliminated, so that bending fracture risks in a driving process of the rotary input member 1300 are avoided, and structural safety is ensured. Illustratively, the center of mass of the rotary input member 1300 is collinear with the center of mass of the movable transmission member 1400 along the direction of linear motion of the movable transmission member 1400.

Illustratively, the rotary input 1300 includes a drive stem end 1320 that remains coupled to a rotary shaft end 1310. The axial direction of the drive stem 1320 is co-planar with the linear reciprocating motion of the movable transmission member 1400, further eliminating the possibility of such external forces acting on the bending moment of the rotary input member 1300. Illustratively, the rotary input member 1300 and the movable transmission member 1400 have symmetrical structures, respectively, and have a coplanar relationship between the symmetry planes thereof.

Illustratively, the mounting base 1100 has a bearing rail 1110 for carrying and guiding the movable transmission member 1400, ensuring that the movable transmission member 1400 always reciprocates linearly. Illustratively, the mounting base 1100 has a limiting portion 1120 for preventing the movable transmission 1400 from overshooting. The limiting portion 1120 is a limiting end wall.

Referring to fig. 4-6, the movable transmission member 1400 has a first clutch end 1410, and the rotary input member 1300 rotates back and forth circumferentially to connect/disconnect the first clutch end 1410. When the rotary input member 1300 is rotationally engaged with the movable transmission member 1400, motion transfer occurs therebetween; when the rotary input member 1300 is separated from the movable transmission member 1400, no motion transmission occurs therebetween.

Under the clutch structure, a flexible transmission relation is formed by the clutch movable space between the rotary input piece 1300 and the movable transmission piece 1400, so that the flexibility of mechanical transmission is enhanced, the position error can be adjusted in a following way, the damage caused by the position error under the rigid direct connection relation is avoided, and the structural safety of the rotary input piece 1300 and the flexibility of rotary operation are further enhanced.

For example, at the circumferential initial position of the liquid outlet stroke, the rotary input member 1300 starts to rotate under the driving of an external force, and at this time, the rotary input member 1300 is kept separate from the movable transmission member 1400, and the motion transmission does not immediately occur to provide a flexible space, so as to avoid interference and jamming; as the rotary input member 1300 rotates to the positive epicyclic engagement position, the rotary input member 1300 engages with the movable transmission member 1400, driving the latter in synchronous linear motion.

For another example, at the circumferential initial position of the reset stroke, the rotation input member 1300 loses the external driving force, at this time, the rotation input member 1300 is separated from the movable transmission member 1400, and the motion transmission does not immediately occur to provide a flexible space, so that interference and jamming are avoided; as the rotary input member 1300 is reversely rotated to the reverse rotation engagement position or the movable transmission member 1400 is slid to the reverse sliding engagement position, the rotary input member 1300 is engaged with the movable transmission member 1400, and power transmission occurs therebetween to cause the passive members therein to synchronously move, thereby achieving the reset and the closing of the push-pull valve 1200.

Illustratively, the first clutch end 1410 has a slotted configuration and the rotary input 1300 has an epicyclic clutch 1330. The rotary input member 1300 rotates back and forth in the circumferential direction to enable the turnover clutch portion 1330 to be inserted into or separated from the slot position structure, so as to achieve the clutch purpose. It will be appreciated that the epicyclic clutch 1330 has consistent synchronous epicyclic with the rotary input 1300. Illustratively, the epicyclic clutch 1330 is a boss protruding from a surface of the rotary input member 1300.

Illustratively, the mounting base 1100 has a circular arc guide 1130 for implementing a rotational guide for the rotational input 1300. The circular arc guide 1130 extends in the rotation direction of the rotation input member 1300, and applies a guide constraint to the rotation input member 1300. Illustratively, the rotary input member 1300 has a guided portion that has a guiding mating relationship with the circular arc guiding portion 1130, and is guided in engagement with each other. The circular arc guide portion 1130 and the guided portion are implemented in a plurality of ways and correspond to each other, for example, one is a guide groove, the other is a flange embedded therein, and the other is a guide rail, a sliding block, and the like. Exemplarily, the guided portion may be served as an epicyclic clutch 1330.

Illustratively, a first resilient element is disposed between the rotary input member 1300 and the mounting base 1100 for effecting circumferential return of the rotary input member 1300. The two ends of the first elastic element are respectively connected with the rotary input piece 1300 and the mounting base 1100, and accumulate elastic deformation energy when the rotary input piece 1300 is driven to rotate by external force, and release the elastic deformation energy when the rotary input piece 1300 loses external driving force, so that the automatic resetting of the rotary input piece 1300 is realized, the push-pull valve 1200 is kept normally closed in a free state, and accidental leakage of liquid is avoided. The first elastic element may be exemplarily acted as a torsion spring.

The liquid dispenser 1000 further includes a sliding seat 1500, wherein two ends of the sliding seat 1500 are respectively connected to the movable driving member 1400 and the push-pull valve 1200, and the sliding seat 1500 is reciprocally retained on the mounting base 1100 to drive the push-pull valve 1200 to be opened and closed in a pushing manner.

In the first movement direction, the sliding seat 1500 moves linearly to drive the valve core 1220 of the push-pull valve 1200 to be conducted, so that the fluid channels are communicated; in the opposite direction to the first movement direction, the sliding seat 1500 moves linearly to drive the valve core 1220 of the push-pull valve 1200 to close, so that the fluid channel is blocked.

The valve core 1220 has a piston structure including a piston cylinder and a piston slidably held in the piston cylinder, one of the piston cylinder and the piston is connected to the sliding seat 1500, the other is connected to the mounting base 1100 or the liquid container, and the opening and closing of the piston of the valve core 1220 is achieved by the relative movement of the sliding seat 1500 and the mounting base 1100/the liquid container. Illustratively, the sliding seat 1500 has a carrying seat 1510 for carrying the push-pull valve 1200 to drive the latter to be opened and closed in a push-pull manner. Illustratively, the mounting base 1100 has an active wall to act on the push-pull valve 1200 in relative proximity to the sliding seat 1500.

The mounting position of the sliding seat 1500 and the mounting base 1100 may be determined according to practical needs, for example, the sliding seat 1500 is at least partially embedded in the mounting base 1100, the sliding seat 1500 slides on the surface of the mounting base 1100, and so on. Illustratively, the mounting base 1100 has a sliding channel that is located inside the mounting base 1100 and that opens to a surface of the mounting base 1100. The sliding seat 1500 is slidably retained in the sliding channel, and two ends of the push-pull valve 1200 respectively penetrate the sliding channel.

Illustratively, the movable transmission member 1400 has a second clutch end 1420, and the movable transmission member 1400 reciprocates linearly such that the second clutch end 1420 is connected to/away from the sliding seat 1500. When the movable transmission member 1400 is slidingly engaged with the sliding seat 1500, a motion transmission occurs therebetween; when the movable transmission member 1400 is separated from the sliding seat 1500, no motion transmission occurs therebetween.

Under the clutch structure, the flexible transmission relation is formed by the clutch movable space between the movable transmission member 1400 and the sliding seat 1500, so that the flexibility of mechanical transmission is enhanced, the position error can be adjusted in a following manner, the damage caused by the position error under the rigid direct connection relation is avoided, and the structural safety and the flexibility of rotation operation of the rotation input member 1300 are further enhanced.

For example, at the sliding start position of the liquid outlet stroke, the movable transmission member 1400 starts to slide under the driving of the rotary input member 1300, and at this time, the movable transmission member 1400 is kept separate from the sliding seat 1500, and the movement transmission does not immediately occur to provide a flexible space, so as to avoid interference and jamming; as the movable transmission member 1400 slides to the forward slide engaging position, the movable transmission member 1400 engages with the slide seat 1500, driving the latter to move linearly in synchronization.

For another example, at the sliding starting position of the reset stroke, the movable transmission member 1400 is kept separate from the sliding seat 1500, and the flexible space is provided without immediate motion transmission, so as to avoid interference and jamming; as the movable transmission member 1400 or the sliding seat 1500 reversely slides to the reverse sliding engagement position, the movable transmission member 1400 engages with the sliding seat 1500, so that the passive member thereof slides synchronously, thereby realizing the reset and the closing of the push-pull valve 1200.

Exemplarily, the sliding seat 1500 has a clutch connection portion 1520, and the clutch connection portion 1520 is used for connecting/separating from the second clutch end 1420. It will be appreciated that the clutch connection 1520 and the slide mount 1500 have consistent linear reciprocation.

The second clutch end 1420 has a first clutch wall 1421 and a second clutch wall 1422, and the first clutch wall 1421 and the second clutch wall 1422 are disposed on two sides of the clutch connection 1520 along the linear reciprocating direction of the movable transmission member 1400. In the forward slide engaged position, the clutch connection 1520 is engaged with the first clutch wall 1421 and disengaged from the second clutch wall 1422; in the reverse slide engaged position, the clutch connection 1520 is engaged with the second clutch wall 1422 and disengaged from the first clutch wall 1421.

Exemplarily, a second elastic element 1600 is disposed between the sliding seat 1500 and the mounting base 1100. The second elastic member 1600 elastically expands and contracts in the linear reciprocating direction of the sliding seat 1500, for achieving the return of the sliding seat 1500, which may be achieved by means of an extension spring, a compression spring, or the like. The first elastic element and the second elastic element 1600 may be alternatively disposed.

Illustratively, the mounting base 1100 has a sliding channel, and the sliding seat 1500 is slidably retained in the sliding channel, and both ends of the push-pull valve 1200 respectively penetrate the sliding channel.

Any particular values in all examples shown and described herein are to be construed as merely illustrative and not a limitation, and thus other examples of exemplary embodiments may have different values.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

The above examples merely represent a few embodiments of the present invention, which are described in more detail and are not to be construed as limiting the scope of the present invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of the invention should be assessed as that of the appended claims.

Claims (7)

1. A liquid dispenser, comprising:

a mounting base for connecting to a liquid container;

the push-pull valve is arranged on the mounting base, is provided with a push-pull opening and closing structure and is in liquid communication with the liquid container;

a rotary input member rotatably held on the mounting base;

the movable transmission piece can be held on the mounting base in a linear reciprocating manner and is used for realizing power transmission between the push-pull valve and the rotary input piece so as to drive the push-pull valve to be opened and closed in a push-pull manner, and the force input end of the rotary input piece and the linear reciprocating movement of the movable transmission piece are distributed in a coplanar manner;

the movable transmission piece is provided with a first clutch end, and the rotary input piece is connected/separated from the first clutch end by rotating in the circumferential direction in a reciprocating manner;

the two ends of the sliding seat are respectively connected with the movable transmission piece and the push-pull valve, and the sliding seat can be held on the mounting base in a linear reciprocating manner so as to drive the push-pull valve to be opened and closed in a push-pull manner;

the movable transmission piece is provided with a second clutch end, and the movable transmission piece linearly reciprocates to enable the second clutch end to be connected with/away from the sliding seat.

2. The liquid dispenser of claim 1, wherein the rotary input member comprises a drive handle end and a rotary shaft end that are connected to each other, the drive handle end having an axial direction that is co-planar with the linear reciprocating motion of the movable transmission member, the rotary shaft end being hinged to the mounting base.

3. The liquid dispenser of claim 1, wherein the mounting base has a circular arc guide for effecting rotational guidance of the rotary input.

4. The liquid dispenser of claim 1, wherein a resilient element is disposed between the rotary input and the mounting base for effecting circumferential return of the rotary input.

5. The liquid dispenser of claim 1, wherein the slide mount has a clutch connection for connecting/disconnecting the second clutch end.

6. The liquid dispenser of claim 1, wherein the second clutch end has a first clutch wall and a second clutch wall that flank the clutch connection in a direction of linear reciprocation of the movable transmission.

7. The liquid dispenser of claim 1, wherein an elastic member is provided between the slide base and the mounting base, and the elastic member elastically expands and contracts in a direction of linear reciprocation of the slide base, for achieving restoration of the slide base.