CN220759786U - Two ingredient adhesive deposite devices - Google Patents

Abstract

The utility model relates to the technical field of glue injection equipment, and discloses a two-component glue dispensing device. The double-component glue dispensing device comprises a fixed plate, a valve body, a first glue feeding mechanism, a second glue feeding mechanism, a first plunger rod, a driving assembly, a first glue discharging mechanism, a second glue discharging mechanism and a mixing pipe, wherein a first one-way valve is arranged on a first glue feeding channel, a fourth one-way valve is arranged on a second glue feeding channel, a second one-way valve is arranged on a first glue discharging channel, and a third one-way valve is arranged on a second glue discharging channel.

Description

Two ingredient adhesive deposite devices

Technical Field

The utility model relates to the technical field of glue injection equipment, in particular to a double-component glue dispensing device.

Background

In the packaging process of the electronic industry, the use of glue dispensing valves to glue components has become popular. The traditional glue dispensing valve inputs glue solution, and the electromagnetic valve drives the firing pin to move, so that the glue solution is impacted by the firing pin to be discharged, and the glue dispensing purpose is achieved. Along with the improvement of the automation degree in the dispensing field, the demand for dispensing is also increasing. The high-viscosity glue solution is generally ultraviolet light UV curing glue, anaerobic glue, conductive silver glue, solder paste, soldering flux, thermal silicone grease, heat conducting gel, epoxy resin and silica gel.

Most of the existing dispensing machines are of a charging barrel direct glue pressing type and a double screw metering type; the material cylinder is directly pressed, the mixing proportion precision is low, and the material cylinder is only suitable for small-sized material cylinders and has complex operation for replacing the material cylinders; the double-screw metering type motor has the advantages of complex structure, complex maintenance, poor stator and rotor wear resistance, short service life, high cost, low constant voltage output precision and high control difficulty.

Disclosure of Invention

The utility model mainly aims to provide a two-component dispensing device, which aims to solve the technical problems that the existing two-component dispensing device is complex in structure and inconvenient to maintain.

In order to achieve the above object, the present utility model provides a two-component dispensing device, which includes: a fixing plate;

the valve body is arranged at one end of the fixed plate;

the first glue feeding mechanism comprises a first needle cylinder, a first glue feeding channel, a first cavity and a first one-way valve, wherein the first needle cylinder is arranged on one side of the fixed plate, the first needle cylinder is communicated with one end of the first glue feeding channel, the other end of the first glue feeding channel is communicated with the first cavity, and the first one-way valve is arranged on the first glue feeding channel;

the second glue feeding mechanism is arranged in a mirror image with the first glue feeding mechanism;

the first plunger rod penetrates through the first cavity and is movably arranged in the first cavity;

the driving component is arranged at the other end of the fixed plate and is abutted against the protruding part of the first plunger rod;

the first glue outlet mechanism comprises a first glue outlet channel and a second one-way valve, the first glue outlet channel is arranged on the valve body and is communicated with the first cavity, and the second one-way valve is arranged on the first glue outlet channel;

the second glue outlet mechanism is arranged in a mirror image with the first glue outlet mechanism;

the mixing pipe is arranged at one end of the valve body, which is far away from the first cavity, and the glue outlet of the first glue outlet channel and the glue outlet of the second glue outlet channel are communicated with the glue inlet of the mixing pipe.

Optionally, in an embodiment, the first check valve includes a sealing pad, a metal ball and a spring that are abutted in sequence, the sealing pad is disposed towards the first syringe, the spring is disposed towards the first cavity, and a structure of the first check valve and a structure of the second check valve are the same structure.

Optionally, in an embodiment, the contact surface of the sealing pad and the metal ball is in a spherical arc shape, and the spherical arc shape is matched with the spherical surface of the metal ball.

Optionally, in an embodiment, the spring compression of the second one-way valve is greater than the spring compression of the first one-way valve.

Optionally, in an embodiment, the two-component dispensing device further includes a first sealing ring and a second sealing ring, where the first sealing ring and the second sealing ring are sequentially sleeved on one end of the first plunger rod located in the first cavity.

Optionally, in an embodiment, the driving assembly includes a driving element and a push rod, the driving element is disposed on an end of the fixing plate away from the valve body, and the push rod is disposed on the driving element and abuts against the first plunger rod.

Optionally, in an embodiment, a surface of the first plunger rod contacting the push rod is a spherical surface, and a surface of the push rod contacting the first plunger rod is a plane surface.

Optionally, in an embodiment, the valve body includes a valve body, a first glue feeding seat and a second glue feeding seat that is mirror-image to the first glue feeding seat, the first glue feeding seat set up in one side of the valve body, the first glue feeding channel includes a first through hole and a first stepped hole, the first through hole set up in on the first glue feeding seat, the first stepped hole set up in on the valve body, the first through hole with the first stepped hole link up, the first check valve set up in the first through hole with the department of link up of first stepped hole.

Optionally, in an embodiment, the first hole has a smaller hole diameter than the first hole diameter of the first stepped hole, and the first hole diameter is larger than the second hole diameter of the first stepped hole.

Optionally, in an embodiment, the second glue feeding mechanism includes a second needle cylinder, a second glue feeding channel, a second cavity and a third one-way valve, the second needle cylinder is disposed on the other side of the fixing plate, the second needle cylinder is connected with one end of the second glue feeding channel, the other end of the second glue feeding channel is connected with the second cavity, and the third one-way valve is disposed on the second glue feeding channel.

According to the technical scheme provided by the utility model, the first one-way valve is arranged in the first glue inlet channel, the fourth one-way valve is arranged in the second glue inlet channel, the second one-way valve is arranged in the first glue outlet channel, and the third one-way valve is arranged in the second glue outlet channel, so that the filling and dispensing of glue A and glue B can be realized, the complex structural design of the rotary valve and the precision matching problem during rotation are avoided, or the complex structural design of the double-screw metering type is avoided, and therefore, the structure of the double-component glue dispensing device is simpler and more reliable, and the double-component glue dispensing device is simpler in structure, so that the double-component glue dispensing device is more convenient to clean and maintain.

Drawings

One or more embodiments are illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements, and in which the figures of the drawings are not to scale, unless expressly stated otherwise.

FIG. 1 is a schematic structural view of a two-component dispensing device according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram of a partial cross-sectional view of one embodiment of the present utility model;

FIG. 3 is a schematic structural diagram showing a filling process of a two-component dispensing device according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of a dispensing process of a two-component dispensing device according to an embodiment of the present utility model.

Wherein, 10, the two-component dispensing device; 11. a fixing plate; 12. a valve body; 121. a valve body; 122. a first glue inlet seat; 123. a second glue inlet seat; 13. a first glue feeding mechanism; 131. a first syringe; 132. a first glue inlet channel; 1321. a first through hole; 1322. a first stepped hole; 133. a first cavity; 134. a first one-way valve; 1341. a sealing gasket; 1342. a metal ball; 1343. a spring; 14. the second glue feeding mechanism; 141. a fourth one-way valve; 142. a second cylinder; 143. a second glue inlet channel; 144. a second cavity; 15. a drive assembly; 151. a driving member; 152. a push rod; 16. a first glue outlet mechanism; 161. a first glue outlet channel; 162. a second one-way valve; 17. a second glue outlet mechanism; 171. a third one-way valve; 18. a mixing tube; 19. a first seal ring; 20. a second seal ring; 21. a spherical surface; 22. a buckle; 23. a first joint; 24. a second joint; 25. a first plunger rod; 26. a second plunger rod.

Detailed Description

In order that the utility model may be readily understood, a more particular description thereof will be rendered by reference to specific embodiments that are illustrated in the appended drawings. 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 one or more intervening elements may be present therebetween. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or one or more intervening elements may be present therebetween. The terms "vertical," "horizontal," "left," "right," "inner," "outer," and the like are used in this specification for purposes of illustration only. In the description of the present utility model, the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating relative importance or implicitly indicating the number of technical features indicated. Thus, unless otherwise indicated, features defining "first", "second" may include one or more such features either explicitly or implicitly; the meaning of "plurality" is two or more. The terms "comprises," "comprising," and any variations thereof, are intended to cover a non-exclusive inclusion, such that one or more other features, integers, steps, operations, elements, components, and/or groups thereof may be present or added.

Furthermore, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; either directly or indirectly through intermediaries, or in communication with each other. 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 utility model belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used in this specification includes any and all combinations of one or more of the associated listed items.

In addition, the technical features mentioned in the different embodiments of the utility model described below can be combined with one another as long as they do not conflict with one another.

The two-component dispensing device can be suitable for mixing various viscosity glues, such as ultraviolet light UV curing glues, anaerobic glues, conductive silver glues, tin pastes, soldering fluxes, thermal silicone grease, heat conducting gels, epoxy resins, silica gel and the like, and can be used in different environments.

Referring to fig. 1-4, a two-component dispensing device 10 is disclosed in an embodiment of the present utility model.

In one embodiment, as shown in fig. 1-4, the two-component dispensing device 10 includes a fixed plate 11, a valve body 12, a first glue feeding mechanism 13, a second glue feeding mechanism 14, a first plunger rod 25, a driving assembly 15, a first glue discharging mechanism 16, a second glue discharging mechanism 17, and a mixing tube 18. Wherein,

the fixing plate 11 plays a fixing role and is disposed with the fixing plate 11 as a reference point.

The valve body 12 is provided at one end of the fixing plate 11, and the valve body 12 controls the direction, pressure and flow rate of the glue during the production process.

The first glue feeding mechanism 13 comprises a first needle cylinder 131, a first glue feeding channel 132, a first cavity 133 and a first one-way valve 134, wherein the first needle cylinder 131 is arranged on one side of the fixed plate 11, one end of the first needle cylinder 131 and one end of the first glue feeding channel 132 are communicated, the other end of the first sharp corner channel is communicated with the first cavity 133, and the first one-way valve 134 is arranged on the first glue feeding channel 132.

The first cylinder 131 is used for storing the A glue, and one end of the first cylinder 131 is communicated with the outside, so that the A glue can be continuously added to the communication part between the first cylinder 131 and the outside in the production process, the continuous feeding of the two-component glue dispensing device 10 is realized, the charging barrel does not need to be frequently replaced, the labor and the time are saved, and the production efficiency is improved.

The first needle cylinder 131 is communicated with the first glue inlet channel 132, so that glue A enters the first glue inlet channel 132 from the needle cylinder; the first one-way valve 134 is that the glue A can only flow along the glue inlet, but the medium at the glue outlet can not flow back; the first cavity 133 temporarily stores the a-glue flowing in through the first glue inlet channel 132. In the production process, air pressure is input to the first needle cylinder 131, the air pressure pushes the glue A stored in the first needle cylinder 131 to move towards the first glue inlet channel 132, and as the air pressure is continuously input to the first needle cylinder 131, the pressure for pushing the glue A to move is larger than the compression force of the spring 1343 of the one-way valve along with the time, so that the glue A pushes the one-way valve open, the first glue inlet channel 132 is opened, the first glue inlet channel 132 is communicated with the first cavity 133, and therefore the glue A can enter the first cavity 133 through the first glue inlet channel 132.

The second glue feeding mechanism 14 and the first glue feeding mechanism 13 are mirror images, the second glue feeding mechanism 14 comprises a second needle cylinder 142, a second glue feeding channel 143, a second cavity 144 and a third one-way valve 171, the second needle cylinder 142 is arranged on the other side of the fixed plate 11, one ends of the second needle cylinder 142 and the second glue feeding channel 143 are communicated with the other ends of the second glue feeding channel 143 and the second cavity 144, and the third one-way valve 171 is arranged on the second glue feeding channel 143.

One side of the fixed plate 11 is opposite to the other side of the fixed plate 11; the second syringe 142 is used for storing the glue B, and the second syringe 142 is communicated with the second glue inlet channel 143, so that the glue B enters the second glue inlet channel 143 from the syringe; the third one-way valve 171 is that the glue B can only flow along the glue inlet, but the medium at the glue outlet can not flow back; the first cavity 133 temporarily stores the B-glue flowing in through the first glue inlet channel 132. In the production process, air pressure is input to the second needle cylinder 142, the air pressure pushes the glue B stored in the second needle cylinder 142 to move towards the second glue inlet channel 143, and as the air pressure is continuously input to the second needle cylinder 142, the pressure for pushing the glue B to move is greater than the compression force of the spring 1343 of the third one-way valve 171 along with the time, so that the glue B pushes the third one-way valve 171 open, and the glue second inlet channel 143 is opened, so that the glue second inlet channel 143 is communicated with the second cavity 144, and therefore the glue B can enter the second cavity 144 through the glue second inlet channel 143.

One end of the first plunger rod 25 penetrates through the first cavity 133, the other end of the first plunger rod 25 is movably arranged in the first cavity 133, the side wall of the first plunger rod 25 abuts against the inner side wall of the first cavity 133, the glue A is prevented from overflowing, and the first plunger rod 25 is used for pushing out the glue A.

The driving assembly 15 is disposed on the other end of the fixed plate 11 and abuts against the protruding portion of the first plunger rod 25, and one end of the fixed plate 11 and the other end of the fixed plate 11 are opposite ends.

The first glue outlet mechanism 16 comprises a first glue outlet channel 161 and a second one-way valve 162, the first glue outlet channel 161 is arranged on the valve body 12 and is communicated with the first cavity 133, and the second one-way valve 162 is arranged on the first glue outlet channel 161; in the production process, the driving assembly 15 drives the first plunger rod 25 to move downwards, so that when the first plunger rod 25 drives the adhesive a to move downwards to the second one-way valve 162, the adhesive a pushes the second one-way valve 162 open due to the pushing force of the driving assembly 15 being greater than the compression amount of the spring 1343 of the second one-way valve 162, thereby opening the first adhesive outlet channel 161, and further enabling the first cavity 133 to communicate with the first adhesive outlet channel 161, so that the adhesive a can flow to the first adhesive outlet channel 161.

The second glue discharging mechanism 17 and the first glue discharging mechanism 16 are arranged in a mirror image mode, the second glue discharging mechanism 17 comprises a second glue discharging channel and a third one-way valve 171, the second glue discharging channel is arranged on the valve body 12 and is communicated with the second cavity 144, the third one-way valve 171 is arranged on the second glue discharging channel, the two-component glue dispensing device 10 further comprises a second plunger rod 26, the second plunger rod 26 and the first plunger rod 25 are arranged in a mirror image mode, one end of the second plunger rod 26 penetrates through the first cavity 133, and the other end of the second plunger rod 26 is movably arranged in the second cavity 144 and abuts against the inner side wall of the second cavity 144; in the production process, the driving assembly 15 drives the second plunger rod 26 to move downwards, so that when the second plunger rod 26 drives the B glue to move downwards to the third one-way valve 171, the driving force of the driving assembly 15 is greater than the compression amount of the spring 1343 of the third one-way valve 171, and therefore the B glue pushes the third one-way valve 171 open, and the second glue outlet channel is opened, and further the second cavity 144 is communicated with the second glue outlet channel, so that the B glue can flow to the second glue outlet channel.

The mixing tube 18 is disposed at an end of the valve body 12 far away from the first cavity 133, the glue outlet of the first glue outlet channel 161 and the glue outlet of the second glue outlet channel are all communicated with the glue inlet of the mixing tube 18, during production, glue a and glue B respectively flow to the glue inlet of the mixing tube 18 through the first glue outlet channel 161 and the second glue outlet channel, and glue a and glue B are mixed in the mixing tube 18.

The two-component dispensing device 10 has two processes of filling and dispensing, wherein, as shown in fig. 3, the filling process is to simultaneously introduce air pressure into the first syringe 131 and the second syringe 142, the first check valve 134 and the fourth check valve 141 are opened, and the glue a and the glue B are not enough to open the second check valve 162 and the third check valve 171, so that the glue a and the glue B enter the first cavity 133 and the second cavity 144 respectively, because the compression amount of the spring 1343 of the second check valve 162 and the compression amount of the spring 1343 of the third check valve 171 are larger than the compression amount of the spring 1343 of the first check valve 134 and the compression amount of the spring 1343 of the fourth check valve 141; the first plunger rod 25 moves upwards under the action of the adhesive A, the first plunger rod 25 moves to the upper limit of the push rod 152, and the first cavity 133 is filled with the adhesive A; the second plunger rod 26 moves upwards under the action of the glue B, the second plunger rod 26 moves to the upper limit of the push rod 152, the glue B is filled in the second cavity 144, the filling process only needs to ensure that the air pressure introduced is larger than the compression amount of the spring 1343 of the first one-way valve 134 and the compression amount of the spring 1343 of the fourth one-way valve 141, the filling of glue A and glue B can be realized, the complex structural design of the rotary valve and the precision matching problem during rotation are avoided, or the complex structural design of the double-screw metering type is avoided, so that the structure of the double-component dispensing device 10 is simpler and more reliable, and the cleaning and the maintenance of the double-component dispensing device are more convenient due to the simple structure.

As shown in fig. 4, the dispensing process: when the first cavity 133 and the second cavity 144 are respectively filled with the glue a and the glue B, the first syringe 131 and the second syringe 142 stop introducing air pressure, the first check valve 134 and the fourth check valve 141 are closed, the driving assembly 15 pushes the first plunger rod 25 and the second plunger rod 26 downwards, and the second check valve 162 and the third check valve 171 are opened; glue A and glue B enter a mixing tube 18 for mixing; according to the required dispensing amount, the driving assembly 15 pushes the first plunger rod 25 and the second plunger rod 26 to displace for a certain distance, and the dispensing can be quantitatively performed by v=s×h, V is the volume of the mixing tube 18, S is the bottom area of the mixing tube 18, and H is the height of the mixing tube 18. In the dispensing process, the mixing of the glue A and the glue B and dispensing after mixing can be realized only by the compression amount of the spring 1343 of the driving force second one-way valve 162 of the driving assembly 15 and the compression amount of the spring 1343 of the third one-way valve 171, so that the complex structural design of the rotary valve and the precision matching problem during rotation are avoided, or the complex structural design of the double-screw metering type is avoided, and therefore, the structure of the double-component dispensing device 10 is simpler and more reliable, and the cleaning and maintenance of the double-component dispensing device are more convenient due to the simple structure

In this embodiment, the first check valve 134 is disposed in the first glue inlet channel 132, the fourth check valve 141 is disposed in the second glue inlet channel 143, the second check valve 162 is disposed in the first glue outlet channel 161, and the third check valve 171 is disposed in the second glue outlet channel, so that the filling and dispensing of glue a and glue B can be achieved, the complex structural design of the rotary valve and the precision matching problem during rotation are avoided, or the complex structural design of the double-screw metering type is avoided, so that the structure of the double-component dispensing device 10 is simpler and more reliable, and the cleaning and maintenance are more convenient due to the simple structure.

In an embodiment, the valve body 12 includes a valve body 121, a first glue feeding seat 122 and a second glue feeding seat 123, the second glue feeding seat 123 is arranged in a mirror image with the first glue feeding seat 122, the first glue feeding seat 122 and the second glue feeding seat 123 are respectively arranged at two opposite sides of the valve body 121, the first glue feeding channel 132 includes a first through hole 1321 and a first stepped hole 1322, the first through hole 1321 is arranged on the first glue feeding seat 122, the first stepped hole 1322 is arranged on the valve body 121, the first through hole 1321 is communicated with the first stepped hole 1322, and the first one-way valve 134 is arranged at a communicating position of the first through hole 1321 and the first stepped hole 1322. In the production process, the adhesive A enters the first through hole 1321 from the first needle cylinder 131 and pushes away the first one-way valve 134 at the through position, so that the adhesive A flows into the first stepped hole 1322 and the first cavity 133 in sequence, and the adhesive feeding channel is mostly straight, so that the structure is simple, and meanwhile, the cleaning dead angle caused by excessive turning positions is avoided, and the cleaning is inconvenient.

The second glue inlet channel 143 includes a second through hole and a second stepped hole, the second through hole is disposed on the second glue inlet seat 123, the second stepped hole is disposed on the valve body 121, the second through hole is communicated with the second stepped hole, and the third one-way valve 171 is disposed at the communication position of the second through hole and the second stepped hole. In the production process, the glue B enters the second through hole from the second needle cylinder 142 and pushes away the third one-way valve 171 at the through position, so that the glue B flows into the second stepped hole and the second cavity 144 in sequence, the glue feeding channel is mostly straight, the structure is simple, and meanwhile, the cleaning dead angle and inconvenient cleaning caused by excessive turning positions are avoided.

Further, the first check valve 134 is disposed at the through position of the first through hole 1321 and the first stepped hole 1322, the first check valve 134 is located in the first hole of the first stepped hole 1322, the aperture of the first through hole 1321 is smaller than the first aperture of the first stepped hole 1322, and the aperture of the first stepped hole 1322 is larger than the second aperture of the first stepped hole 1322, so that the first check valve 134 abuts against between the first through hole 1321 and the second hole of the first stepped hole 1322, and the first check valve 134 has resetting elasticity, so that the first check valve 134 abuts against and seals at the glue outlet of the first through hole 1321 in a normal state, thereby improving the sealing effect of the two-component glue dispensing device 10.

Specifically, the fourth check valve 141 is disposed at the through position of the second through hole and the second stepped hole, the fourth check valve 141 is disposed in the first hole of the second stepped hole, and the aperture of the second through hole is smaller than the third aperture of the second stepped hole, so that the fourth check valve 141 abuts against between the second through hole and the second space of the second through hole, and the fourth check valve 141 has resetting elasticity, so that the fourth check valve 141 abuts against and seals at the glue outlet of the second through hole in a normal state, thereby improving the sealing effect of the two-component glue dispensing device 10.

Further, the first check valve 134 includes a sealing pad 1341, a metal ball 1342 and a spring 1343 which are sequentially abutted, and the first check valve 134 has a simple structure and is convenient to install, disassemble and clean. The packing 1341 is disposed toward the first cylinder 131, and the spring 1343 is disposed toward the first chamber 133, and the structure of the first check valve 134, the structure of the second check valve 162, the structure of the third check valve 171, and the structure of the fourth check valve 141 are the same. Specifically, the metal balls 1342 may be steel balls, aluminum balls, magnesium balls, titanium balls, strontium balls, or barium balls. The sealing pad 1341 is disposed at the through position of the first through hole 1321 and the first stepped hole 1322, i.e. one end of the sealing pad 1341 is disposed in the through hole, the other end is disposed in the first stepped hole 1322, so as to avoid the overflow of the adhesive a from the through position of the first through hole 1321 and the first stepped hole, improve the tightness of the two-component adhesive dispensing device 10, and the metal ball 1342 is disposed between the sealing pad 1341 and the spring 1343, and the metal ball 1342 can be abutted against the sealing pad 1341 due to the elasticity of the spring 1343, so that the metal ball 1342 blocks the adhesive outlet of the first through hole 1321 in a normal state, and the adhesive a can not pass through.

Wherein the amount of compression of the springs 1343 of the second and third check valves 162 and 171 is greater than the amount of compression of the springs 1343 of the first and fourth check valves 134 and 141. Illustratively, the springs 1343 in the first, second, third, and fourth check valves 134, 162, 171, 141 are identical, and the hole depths of the first and fourth check valves 134, 141 are greater than the hole depths of the second and third check valves 162, 171, such that the springs 1343 of the first and fourth check valves 134, 141 compress less than the springs 1343 of the second and third check valves 162, 171, i.e., the same springs 1343, are compressed tighter within a shorter hole depth, the greater the amount of compression thereof.

In this embodiment, the one-way valves are disposed in the channels of the two-component dispensing device 10, and the one-way valves have a simple structure, so that the two-component dispensing device 10 has a simple internal structure and is convenient to clean and maintain.

In an embodiment, the contact surface of the sealing pad 1341 with the metal ball 1342 is in a spherical arc shape, and the spherical arc shape is matched with the spherical surface of the metal ball 1342, so that the metal ball 1342 can be better attached to the sealing pad 1341, and the sealing effect is improved.

As shown in fig. 1-4, in one embodiment, the driving assembly 15 includes a driving member 151 and a push rod 152, the driving member 151 is disposed on an end of the fixed plate 11 away from the valve body 12, and the push rod 152 is telescopically disposed on the driving member 151 and abuts the first plunger rod 25 and the second plunger rod 26. The driver 151 drives the push rod 152 to push the first plunger rod 25 and the second plunger rod 26 to move downward, thereby achieving mixing and dispensing of the glue a and the glue B. The materials of the first plunger rod 25 and the second plunger rod 26 adopt high-hardness wear-resistant alloy, so that the service lives of the first plunger rod 25 and the second plunger rod 26 are prolonged. Specifically, the driving member 151 may be a motor or a cylinder.

When the driving member 151 is a motor, the two-component dispensing device 10 has a function of high-precision quantitative proportioning. The dispensing process is exemplified by: when the first cavity 133 and the second cavity 144 are respectively filled with the glue a and the glue B, the first syringe 131 and the second syringe 142 stop introducing air pressure, the first check valve 134 and the fourth check valve 141 are closed, the motor drives the push rod 152 to push the first plunger rod 25 and the second plunger rod 26 downwards, and the second check valve 162 and the third check valve 171 are opened; glue A and glue B enter a mixing tube 18 for mixing; according to the required dispensing amount, the motor pushes the first plunger rod 25 and the second plunger rod 26 to displace for a certain distance, and the dispensing can be performed with high precision by v=s×h, V is the volume of the mixing tube 18, S is the bottom area of the mixing tube 18, and H is the height of the mixing tube 18.

When the driving member 151 is an air cylinder, the two-component dispensing device 10 has a constant-pressure mixing feeding function. Illustratively, the mixing process is: when the first cavity 133 and the second cavity 144 are respectively filled with the glue a and the glue B, the first syringe 131 and the second syringe 142 stop introducing air pressure, the first check valve 134 and the fourth check valve 141 are closed, the cylinder driving push rod 152 pushes the first plunger rod 25 and the second plunger rod 26 downwards, and the second check valve 162 and the third check valve 171 are opened; glue A and glue B enter a mixing tube 18 for mixing; the constant pressure glue after mixing is fed out from the mixing tube 18.

Further, the surface of the first plunger rod 25 contacting the push rod 152 is a spherical surface 21, the surface of the second plunger rod 26 contacting the push rod 152 is a spherical surface 21, the deflection error of the first plunger rod 25 and the second plunger rod 26 is compensated, and the surface of the push rod 152 contacting the first plunger rod 25 and the second plunger rod 26 is a plane, thereby allowing the first plunger rod 25 and the second plunger rod 26 to deflect and move in a small space.

Further, the two-component dispensing device 10 further includes a first sealing ring 19 and a second sealing ring 20, the first sealing ring 19 and the second sealing ring 20 are sequentially sleeved on one end of the first plunger rod 25 located in the first cavity 133, specifically, a first groove and a second groove are respectively provided on one end of the first plunger rod 25 located in the first cavity 133, the first sealing ring 19 is sleeved on the first plunger rod 25 and located in the first groove, and the first sealing ring 19 is elastic, so that when the first sealing ring 19 is squeezed in the first groove, an expansion tension force is provided to enable the first sealing gasket 1341 to be always squeezed on the inner side wall of the first cavity 133, so that the sealing effect of the two-component dispensing device 10 is improved, the second sealing ring 20 is sleeved on the second plunger rod 26 and located in the second groove, and the second sealing ring 20 is elastic, so that when the second sealing ring 20 is squeezed in the second groove, an expansion tension force is provided to enable the second sealing ring 20 to be always squeezed on the inner side wall of the first cavity 133, and the sealing effect of the two-component dispensing device 10 is further improved.

In an embodiment, the two-component dispensing device 10 further includes a buckle 22, the mixing tube 18 is correspondingly provided with a plurality of bumps, the bumps are rotationally clamped into the buckle 22, and the connection stability of the mixing tube 18 is further improved.

As shown in fig. 1-4, further, the two-component dispensing device 10 further includes a first connector 23 and a second connector 24, the first connector 23 is disposed between the first syringe 131 and the first glue inlet seat 122, so as to improve the connection tightness between the first syringe 131 and the first glue inlet seat 122, and the second connector 24 is disposed between the second syringe 142 and the second glue inlet seat 123, so as to improve the connection tightness between the second syringe 142 and the second glue inlet seat 123. Specifically, the first connector 23 and the second connector 24 may be luer connectors, and the luer connectors are standardized micro-non-seepage connectors, so that the sealing performance of the two-component dispensing is improved.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; the technical features of the above embodiments or in the different embodiments may also be combined within the idea of the utility model, the steps may be implemented in any order, and there are many other variations of the different aspects of the utility model as described above, which are not provided in detail for the sake of brevity; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (10)

1. The utility model provides a two ingredient dispensing device which characterized in that, two ingredient dispensing device includes:

a fixing plate;

the valve body is arranged at one end of the fixed plate;

the first glue feeding mechanism comprises a first needle cylinder, a first glue feeding channel, a first cavity and a first one-way valve, wherein the first needle cylinder is arranged on one side of the fixed plate, the first needle cylinder is communicated with one end of the first glue feeding channel, the other end of the first glue feeding channel is communicated with the first cavity, and the first one-way valve is arranged on the first glue feeding channel;

the second glue feeding mechanism is arranged in a mirror image with the first glue feeding mechanism;

the first plunger rod penetrates through the first cavity and is movably arranged in the first cavity;

the driving component is arranged at the other end of the fixed plate and is abutted against the protruding part of the first plunger rod;

the first glue outlet mechanism comprises a first glue outlet channel and a second one-way valve, the first glue outlet channel is arranged on the valve body and is communicated with the first cavity, and the second one-way valve is arranged on the first glue outlet channel;

the second glue outlet mechanism is arranged in a mirror image mode with the first glue outlet mechanism, and comprises a second glue outlet channel;

the mixing pipe is arranged at one end of the valve body, which is far away from the first cavity, and the glue outlet of the first glue outlet channel and the glue outlet of the second glue outlet channel are communicated with the glue inlet of the mixing pipe.

2. The two-component dispensing device of claim 1, wherein the first one-way valve comprises a gasket, a metal ball and a spring which are sequentially abutted, the gasket is arranged towards the first syringe, the spring is arranged towards the first cavity, and the structure of the first one-way valve and the structure of the second one-way valve are the same.

3. The two-component dispensing device of claim 2, wherein the gasket is in contact with the metal ball and has a spherical arc shape, and the spherical arc shape is matched with the spherical surface of the metal ball.

4. The two-component dispensing device of claim 2, wherein the second one-way valve has a greater amount of spring compression than the first one-way valve.

5. The two-component dispensing device of claim 1, further comprising a first sealing ring and a second sealing ring, wherein the first sealing ring and the second sealing ring are sequentially sleeved on one end of the first plunger rod located in the first cavity.

6. The two-component dispensing device of claim 1, wherein the drive assembly comprises a driver disposed on an end of the fixed plate remote from the valve body and a pushrod disposed on the driver and in abutment with the first plunger rod.

7. The two-component dispensing device of claim 6, wherein the surface of the first plunger rod in contact with the push rod is spherical and the surface of the push rod in contact with the first plunger rod is planar.

8. The two-component dispensing device of claim 1, wherein the valve body comprises a valve body, a first glue inlet seat and a second glue inlet seat arranged in a mirror image with the first glue inlet seat, the first glue inlet seat is arranged on one side of the valve body, the first glue inlet channel comprises a first through hole and a first stepped hole, the first through hole is arranged on the first glue inlet seat, the first stepped hole is arranged on the valve body, the first through hole is communicated with the first stepped hole, and the first one-way valve is arranged at the communication position of the first through hole and the first stepped hole.

9. The two-component dispensing device of claim 8, wherein the first through hole has a smaller aperture than a first aperture of the first stepped hole, the first aperture being larger than a second aperture of the first stepped hole.

10. The two-component dispensing device of claim 1, wherein the second glue feeding mechanism comprises a second needle cylinder, a second glue feeding channel, a second cavity and a third one-way valve, the second needle cylinder is arranged on the other side of the fixed plate, the second needle cylinder is communicated with one end of the second glue feeding channel, the other end of the second glue feeding channel is communicated with the second cavity, and the third one-way valve is arranged on the second glue feeding channel.