TWI661872B - Multi-function drainage module and fluid drainage transfer method - Google Patents

Abstract

A multi-functional drainage module and a fluid drainage transfer method. The multi-functional drainage module is installed in a module assembly room of a mold base thereof as a transfer fluid component. The drainage composite module is provided with a contact on one side of a module body. The end block portion, the module body and the contact end block portion each include a plurality of crosslinked micro particles and an open microporous structure located between the plurality of crosslinked micro particles to disperse and evenly drain the to-be-transferred The fluid and multi-function drainage module also has a fluid supply pipeline and a fluid recovery pipeline in the mold base that communicate with the module assembly chamber for supplying fluid and recovered fluid. The fluid drainage transfer method uses a multi-function drainage mold. The group performs the transfer fluid operation on the surface of the workpiece, and can recover the fluid in order to effectively control the fluid output and the uniformity of the fluid transfer.

Description

Multi-function drainage module and fluid drainage transfer method

The invention relates to a multi-function drainage module and a fluid drainage transfer method, which are used for fluid coating and transfer operations on the surface of a workpiece.

In the past, in the pasting operation of glass and other plates, the plates were erected and then each side of the plate was glued one by one with a glue application device. However, in the pre-uncovering sheet coating operation method, after completing the gluing step on one side of the sheet, the sheet must be reversed to perform the gluing step on the other side of the sheet. The problem of deviation occurs in the position, and the glue application device is difficult to control the amount of glue, and easy to overflow.

In order to overcome the problem of misalignment caused by the above-mentioned plate turning, someone has further proposed a siphon-type plate gluing device, which places the plate horizontally on a movable and horizontally rotating platform, and moves the plate through the platform to make the plate The side edge contacts the porous gluing element with the adhesive adsorbed in the siphon type sheet gluing device, and the adhesive is transferred from the gluing side of the gluing element to the side of the sheet by the siphon principle.

However, when the aforementioned siphon-type plate gluing device is used, although the method of horizontally rotating the plate is used to reduce the problem of misalignment when the plate is reversed, the glue is applied to the side of the plate by siphoning to reduce the phenomenon of glue overflow. However, although the glued components used in the siphon-type board gluing device are porous materials such as foam and have the function of adsorbing adhesive, the structure of the foamed porous glued components is not completely open. Structure, the adhesive is not easy to evenly distribute the pressure, and the siphon-type plate gluing device does not have an adhesive recovery mechanism, which makes it difficult to reach the coating under the condition that the output pressure of the adhesive is difficult to uniformly distribute. The amount of glue on the rubber surface is difficult to control, and the glue on the rubberized surface is prone to sag due to gravity, so it is necessary to further improve it.

The purpose of the present invention is to provide a multi-functional drainage module and a fluid drainage transfer method, which solve the problems that the porous adhesive components used in the existing siphon plate adhesive device are difficult to uniformly disperse the adhesive, and do not have the adhesive recovery function. .

In order to achieve the purpose of the previous disclosure, the multi-function drainage module system proposed by the present invention includes: a mold base, whose opposite sides are a fluid transfer side and a back side, respectively, and the mold base includes a module assembly chamber, a fluid A supply line and a fluid recovery line, the module assembly chamber extends from the inside of the mold base toward the fluid transfer side, and an opening is formed on the fluid transfer side, and the fluid supply line is located in the A position above the module assembly chamber, and the fluid supply pipeline extending inward from the outer side of the mold base to communicate with the module assembly chamber, the fluid recovery pipeline is located below the module assembly chamber, and the fluid The recovery pipeline extends inwardly from the outer side of the mold base to communicate with the module assembly room; and a drainage composite module is provided in the module assembly room of the mold base. The drainage composite module includes a module body and A contact end block portion is provided at one end of the module body, and the contact end block portion is a fluid transfer surface with respect to the other end of the module body, and the material hardness of the contact end block portion is less than that of the module Ontology Material hardness, the module body and the contact end block each include a plurality of cross-linked plastic micro-particles of general use, and an open micro-porous structure is formed between the plurality of cross-linked micro-particles. The open microporous structure includes a plurality of dispersed and interconnected micropores to form a three-dimensional network. The module body and the open microporous structure of the contact end block portion are dispersedly extended to each peripheral surface and communicate with each other to form a plurality. With open holes, the contact end block portion of the drainage composite module protrudes outside the opening on the fluid transfer side of the mold base.

Created by the drainage composite module in the previously-disclosed multi-function drainage module, when it is applied to a fluid transfer mechanism, the contact end block of the drainage composite module with less hardness is used as the transfer fluid component of the contact object, and the The introduced fluid can sequentially pass through the open microporous structure of the module body and the open microporous structure of the contact end block portion, and the fluid can be uniformly dispersed during the process of fluid drainage to the fluid transfer surface of the outer end portion of the contact end block portion. And, the fluid reaching the fluid transfer surface can be moderately decompressed, and the amount of fluid in the fluid transfer surface can be effectively controlled to avoid the phenomenon of excessive concentration of fluid. In addition, the use of a less rigid contact end block as a transfer fluid component for contacting an object can also improve the adhesion of the drainage composite module to the object, overcome the micro tolerance between the object and the drainage composite module, and ensure the composition through drainage The fluid of the module can be accurately transferred to the surface of the object.

In addition, the module body and the contact end block portion of the drainage composite module have an open microporous structure that is cross-linked with most of their micro particles, so that the fluid transfer surface contacting the end block portion is formed by a plurality of micro particles. The smooth and rough surface provides more fluid attachment area. In combination with the aforementioned decompression performance, it can reduce the unevenness of the fluid reaching the fluid transfer surface due to gravity, so that the fluid on the fluid transfer surface can maintain a good uniformity. Sex.

In order to achieve the purpose of the previous disclosure, the fluid drainage transfer method provided by the present invention uses a multi-function drainage module as described above. The fluid drainage transfer method includes: entering fluid into a mold base of the multi-power drainage module. The fluid is guided to the drainage composite module through the fluid supply pipeline of the mold base; the fluid is dispersed and drained to the drainage micro-structure through the open micro-porous structure of the module body of the drainage composite module and the open micro-porous structure in contact with the end block. Fluid transfer surface; connecting the fluid recovery pipeline in the middle section of the drainage composite module through the mold base to recover excess fluid; and The fluid transfer of the drainage composite module faces a workpiece transfer fluid, and the workpiece to be transferred is brought into contact with the fluid transfer surface of the drainage composite module, so that the fluid drained to the fluid transfer surface is transferred to the workpiece. Side end surface, and then move away from the workpiece.

Created by using a multi-functional drainage module and a fluid drainage transfer method, when it is applied to the side of an object such as a workpiece to coat or transfer fluid, it uses the drainage composite module in the multi-functional drainage module to provide fluid. It can evenly disperse, effectively control the amount of fluid on the fluid transfer surface, and ensure that the fluid reaching the fluid transfer surface maintains good uniformity. It also further uses the fluid supplied to the mold base of the multi-function drainage module to supply fluid. In the material pipeline, the open microporous structure of the module body of the drainage composite module and the open microporous structure of the contact end block portion enable the fluid to be dispersed and uniformly drained to the fluid transfer surface, and the fluid is supplied. When there is too much fluid, the fluid can be recycled through the fluid recovery pipeline connected to the middle section of the drainage composite module to guide the fluid recovery mechanism to ensure that the fluid that is drained to the fluid transfer surface of the drainage composite module can maintain a stable supply and effectively avoid the fluid. Overflow phenomenon.

1‧‧‧Multi-function drainage module

10‧‧‧Mould base

11‧‧‧Modular assembly room

111‧‧‧ opening

12‧‧‧ fluid supply pipeline

13‧‧‧ fluid recovery pipeline

20‧‧‧Drainage composite module

21‧‧‧Module body

22‧‧‧ Contact end block

221‧‧‧fluid transfer surface

23A, 23B‧‧‧Micro particles

24A, 24B‧‧‧Open microporous structure

30‧‧‧ Workpiece

FIG. 1 is a schematic perspective view of a preferred embodiment of a drainage composite module according to the present invention.

FIG. 2 is an enlarged schematic view showing a preferred embodiment of the drainage composite module shown in FIG. 1 showing a plurality of micro-particles cross-linked to each other and an open micro-porous structure formed between the micro-particles cross-linked to each other.

FIG. 3 is a schematic side sectional view of a preferred embodiment of the multi-function drainage module of the present invention.

FIG. 4 is a reference diagram of the use state of the preferred embodiment of the multi-power drainage module shown in FIG. 3.

The present invention includes a multi-function drainage module and a fluid drainage transfer method. The multi-function drainage module includes a drainage composite module. The following is a further explanation of the present invention in order to achieve a predetermined invention in conjunction with the drawings and preferred embodiments of the present invention. The technical means adopted for the purpose.

As shown in FIG. 1 and FIG. 2, a preferred embodiment of a drainage composite module 20 used in the multi-function drainage module of the present invention is disclosed. The drainage composite module 20 includes a module body 21 and a contact end block 22. The contact end block portion 22 is provided at one end of the module body 21, and the other end of the contact end block portion 22 with respect to the module body 21 is a fluid transfer surface 221. The module body 21 and the contact end block portion 22 both include Components of the open microporous structure 24A, 24B, and the open microporous structure 24A, 24B of the module body 21 and the contact end block portion 22 are dispersedly extended to each peripheral surface thereof to form a plurality of open holes. The material hardness of the contact end block portion 22 is smaller than the material hardness of the module body 21. The module body 21 may be a hard component and the contact end block portion 22 may be a soft component.

As shown in FIG. 1 and FIG. 2, the module body 21 and the contact end block portion 22 each include a plurality of micro-particles 23A and 23B of general plastic material, and most of the micro-particles 23A and 23B are crosslinked by foam and High-frequency compression molding enables the open microporous structures 24A and 24B to be formed between the plurality of micro-particles 23A and 23B that are cross-linked with each other. As shown in FIG. 2, the open microporous structure includes a plurality of fine pores that are dispersed and communicate with each other to form a three-dimensional network.

In this preferred embodiment, the universal plastic material may be hydrophilic or lipophilic, and the universal plastic material may be selected from Polyurethane (PU), Polyethylene (PE), or Polytetrafluoroethylene. Polytetrafluoroethylene (commonly known as Teflon), etc., the material selection of the module body 21 and the contact end block portion 22 is determined by referring to the use conditions (such as the fluid material, etc.).

The front peeling drainage composite module 20 can be applied to a drainage module or other fluid transfer forming mechanism such as fluid coating and transfer to perform fluid transfer operations such as workpiece transfer and gluing. Among them, the drainage composite module 20 is used The contact end block portion 22 having a relatively small hardness is used as a transfer fluid component of the contact object, A process in which the introduced fluid can sequentially pass through the open microporous structure 24A of the module body 21 and the open microporous structure 24B of the contact end block portion 22, and the fluid is drained to the fluid transfer surface 221 of the contact end block portion 22 In this way, the fluid can be evenly dispersed, and the fluid can be decompressed moderately when it reaches the fluid transfer surface 221, and the amount of fluid located on the fluid transfer surface 221 can be effectively controlled to avoid excessive concentration of fluid.

Moreover, the drainage composite module 20 has an open microporous structure by using most of its microparticles cross-linked to each other, so that it contacts the fluid transfer surface 221 of the end block portion 22 to form a non-smooth rough surface by a plurality of microparticles 23B, providing The attachment area with more fluids, combined with the aforementioned decompression performance, can reduce the phenomenon that the fluid reaching the fluid transfer surface 221 sags unevenly due to gravity, so that the fluid on the fluid transfer surface 221 maintains good uniformity.

As shown in FIG. 3, a preferred embodiment of the multi-function drainage module 1 of the present invention is disclosed. As can be seen from the figure, the multi-function drainage module 1 includes a mold base 10 and a drainage composite. Module 20.

As shown in FIG. 3, the opposite sides of the mold base 10 are a fluid transfer side and a back side, respectively. The mold base 10 includes a module assembly chamber 11, a fluid supply pipeline 12 and a fluid recovery pipeline 13. The module assembly chamber 11 extends from the inside of the mold base 10 toward the fluid transfer side and forms an opening 111 on the fluid transfer side. The fluid supply pipe 12 extends inward from the outer side of the mold base 10 and The module assembly chamber 11 communicates with the fluid supply pipeline 12 at a position above the module assembly chamber 11. The fluid recovery pipeline 13 is located below the module assembly chamber 11, and the fluid recovery pipeline 13 extends inwardly from the outer side of the mold base 10 to communicate with the module assembly chamber 11. In this preferred embodiment, The fluid supply pipe 12 extends from the back side of the mold base 10 and connects to the upper side of the module assembly chamber 11 facing the back side. The fluid recovery pipe 13 extends from the back side of the mold base 10 to connect the module assembly room. The bottom side of the middle section of 11.

The drainage composite module 20 is located in the module assembly chamber 11 of the mold base 10, and the contact end block portion 22 of the drainage composite module 20 protrudes outside the opening 111 on the fluid transfer side of the mold base 10 so that the contact end The fluid transfer surface 221 of the block portion 22 is located outside the fluid transfer side of the mold base 10.

As shown in FIG. 4, the multi-function drainage module 1 can be applied to fluid transfer molding equipment such as workpiece transfer or gluing. The fluid supply pipeline 12 of the mold base 10 is connected to a fluid supply mechanism. The fluid recovery line 13 of the base 10 is connected to a fluid recovery mechanism, whereby the fluid supply mechanism sends liquid fluid to the fluid supply line 12 of the mold base 10 of the multi-function drainage module 1, and then passes through the drainage. The open microporous structure 24A of the module body 21 of the composite module 20 and the open microporous structure 24B of the contact end block portion 22 enable the fluid to be dispersed and uniformly drained to the fluid transfer surface 221 to provide the surface of the workpiece 30 such as a plate Applications such as coating fluids and transfer fluids.

In addition, the multi-function drainage module 1 uses the contact end block portion 22 of the drainage composite module 20 that has a relatively low hardness as a fluid transfer component that contacts the workpiece 30, which can improve the contact fit between the drainage composite module 20 and the workpiece. In order to overcome the micro tolerance between the workpiece and the drainage composite module 22, it is ensured that the fluid passing through the drainage composite module 20 can be accurately coated on the surface of the workpiece 30.

When the fluid supply is too large, the fluid can be recycled to the fluid recovery mechanism through the fluid recovery pipeline 13 connected to the middle portion of the drainage composite module 20 to ensure that the fluid drained to the fluid transfer surface 221 of the drainage composite module 20 can maintain stability. The amount of supply effectively prevents fluid overflow.

The fluid drainage transfer method of the present invention is to expose a multi-function drainage module before use. The implementation steps include: entering fluid into the mold base of the multi-function drainage module, which passes the fluid through the mold of the multi-function drainage module. The fluid supply pipeline of the seat is guided into the drainage composite module; the fluid is drained to the fluid transfer surface through the open microporous structure in the drainage composite module, which is through the open microporous structure of the module body and the opening of the contact end block. The microporous structure is dispersed and drained to the fluid transfer surface of the contact end block; the excess fluid is guided to the recycling mechanism for reuse by connecting the fluid recovery pipeline at the middle portion of the drainage composite module; and The fluid transfer of the drainage composite module faces a workpiece transfer fluid, which causes the workpiece to be transferred to contact the fluid transfer surface of the drainage composite module, so that the fluid drained to the fluid transfer surface is transferred to the workpiece. After the side end surface, move away from the workpiece.

As can be seen from the above description, the present invention utilizes the contact end block with a lower hardness in the pre-exposure drainage composite module as a fluid transfer part contacting the workpiece, and enables the introduced fluid to sequentially pass through the open microporous structure of the module body. The open microporous structure in contact with the end block portion, while being drained to the fluid transfer surface at the outer end of the contact end block portion, the fluid can be uniformly dispersed, and the fluid reaching the fluid transfer surface can be decompressed moderately, and Can effectively control the amount of fluid on the fluid transfer surface and avoid excessive concentration of fluid. In addition, the module body of the drainage composite module and most of the micro-particles in the contact end block portion are cross-linked with each other to have an open microporous structure. The adhesion area, combined with the aforementioned decompression performance, can reduce the phenomenon that the fluid reaching the fluid transfer surface sags unevenly due to gravity, so that the fluid on the fluid transfer surface can maintain good uniformity.

In addition, the invention of the multi-functional drainage module and fluid drainage transfer method of the present invention, in addition to using the drainage composite module to provide uniform fluid dispersion, effectively control the amount of fluid on the fluid transfer surface, and ensure that the fluid reaches the fluid transfer surface In addition to maintaining good uniformity and other functions, the fluid is further transferred to the fluid supply pipeline of the mold base of the multi-function drainage module, and then passes through the open microporous structure and contact end of the module body of the drainage composite module. The open microporous structure of the block allows the fluid to be dispersed and uniformly drained to the fluid transfer surface, and when the fluid supply is too large, the fluid can be guided to the fluid recovery mechanism through the fluid recovery pipeline connected to the middle part of the drainage composite module Recycling ensures that the fluid drained to the fluid transfer surface of the drainage composite module can maintain a stable supply amount and effectively avoid the phenomenon of fluid overflow.

Claims (4)

A multi-function drainage module includes: a mold base, whose opposite sides are a fluid transfer side and a back side, respectively; the mold base includes a module assembly chamber, a fluid supply pipeline and a fluid recovery tube The module assembly room extends from the inside of the mold base toward the fluid transfer side, and an opening is formed on the fluid transfer side. The fluid supply pipeline is located above the module assembly room, and the The fluid supply pipeline extends inwardly from the outer side of the mold base to communicate with the module assembly chamber. The fluid recovery pipeline is located below the module assembly chamber, and the fluid recovery pipeline is from the mold base. The outer side extends inwardly to communicate with the module assembly room; and a drainage composite module is provided in the module assembly room of the mold base. The drainage composite module includes a module body and a contact end block portion, and the contact end block portion The contact end block portion is a fluid transfer surface with respect to the other end of the module body, the material hardness of the contact end block portion is less than that of the module body, and the module body and the Pick up The end blocks each include a plurality of micro-particles of general plastic material cross-linked to each other, and an open micro-porous structure is formed between the plurality of micro- particles cross-linked to each other, and the open micro-porous structure contains a majority The dispersed and interconnected micropores form a three-dimensional network. The module body and the open microporous structure of the contact end block are dispersedly extended to each peripheral surface and communicate with each other to form a plurality of open holes. The drainage composite module The contact end block portion protrudes outside the opening on the fluid transfer side of the mold base. The multi-function drainage module according to claim 1, wherein the module body is a hard component, and the contact end block portion is a soft component. The multi-function drainage module according to claim 1 or 2, wherein the fluid supply pipeline extends from the back side of the mold base and connects to the upper side of the section where the module assembly chamber faces the back side, and the fluid is recovered The pipeline extends from the back side of the mold base and connects to the bottom side of the middle section of the module assembly room. A fluid drainage transfer method using the multi-function drainage module according to any one of claims 1 to 3. The fluid drainage transfer method includes: entering fluid into a mold base of the multi-function drainage module. The fluid is guided to the drainage composite module through the fluid supply pipeline of the mold base; the fluid is drained to the fluid through the open microporous structure of the module body of the drainage composite module and the open microporous structure in contact with the end block. A transfer surface; a fluid recovery pipeline connected to a middle portion of the drainage composite module through the mold base to recover excess fluid; and the fluid transfer of the drainage composite module to a workpiece transfer fluid, which is the workpiece to be transferred After contacting the fluid transfer surface of the drainage composite module, the fluid drained to the fluid transfer surface is transferred to the side end surface of the workpiece, and then moved away from the workpiece.