KR810001445B1 - Solvent bonded joint and method of making the same - Google Patents

Abstract

The method of joining two plastic members comprising forming said members for frictional engagement therebetween in a fluid-tight zone of interference with a tapered crevice leading to said zone of interference, fitting said members together in frictional engagement with said zone of interference serving as a fluid-tight barrier, and introducing a solvent into said crevice at a point remote from said zone of interference to form a solvent bond with said zone of interference serving as a barrier against contact between said solvent and any flowable material or objects on the opposite side of said zone.

Description

Manufacturing method of solvent adhesive joint

1A is a cross-sectional view taken along an axis of a pharmaceutical liquid control chamber using the method for producing a solvent-bonded joint according to the present invention.

FIG. 2a is a cross-sectional view taken along the axis of the control chamber showing the junction according to the invention, excluding the valve member and separating portions of the control chamber of FIG.

FIG. 3a is a cross-sectional view of the control room taken along line 3-3 of FIG. 1a showing the junction according to the invention.

FIG. 4A is an enlarged cross-sectional view of a portion (indicated by a circle) of the control chamber of FIG. 1A showing the joint according to the present invention before the solvent enters and the solvent adhesion is performed.

FIG. 5A is an enlarged cross-sectional view of a part of the control chamber of FIG. 1A showing the joint according to the present invention while the solvent enters and the solvent adhesion is performed.

Figure 6a is a cross-sectional view taken along the axis showing another method of producing a solvent adhesive joint according to the present invention.

Figure 1b is a front view of a bag (bag) to be used for the administration of a pharmaceutical solution using the method for producing a solvent adhesive junction according to the present invention.

Figure 2b is a longitudinal sectional view showing the assembly just before the solvent input and dissolution.

3b is a side view showing the parts in an exploded state.

Figure 4b is an enlarged longitudinal cross-sectional view of the portion circled in Figure 2.

FIG. 5B is an enlarged cross sectional view taken along line 5-5 of FIG. 2B.

Fig. 6B is an enlarged longitudinal sectional view showing the joint of the present invention while the solvent is added and the solvent bonding is performed.

FIG. 7B is a partial sectional view showing parts after solvent dissolution. FIG.

Various methods have been used, such as heat sealing and solvent bonding, to permanently bond the plastic parts to seal the fluid. Heat sealing is widely used, but sophisticated support is needed to achieve reliability and yield in the assembly of relatively small plastic parts such as filter housings, couplings, outlets, etc. which are commonly used in medical devices. An apparatus and an operating mechanism are necessary.

Solvent sealing, in which the solvent is applied to one side before the two parts are fitted, may be advantageous, but there is a limitation in mass productivity. Once the solvent has been applied, the parts must be assembled immediately. However, for example, a batch-type operation of applying and then assembling a solvent in several parts is not possible. In addition, when the liquid is contained in (or in contact with) the liquid, the conventional solvent application and assembly process is not only awkward and unnatural, but also causes problems when the liquid adheres to the solvent, and the solvent may get into the liquid. The contact of the liquid with the solvent is obviously poor, especially when the liquid (parenteral fluid) is contaminated.

Summary of the Invention The gist of the present invention assembles the parts and temporarily seals them so that they do not leak liquid, and then flows a suitable solvent for the plastic material into the indented end, where the solvent enters the indent by the capillary action. It is to overcome the shortcomings of technology. Temporary sealing serves as a barrier against capillary entry of the solvent and prevents liquid and solvent from contacting by the overlapping parts of the liquid when a liquid such as a parenteral liquid is across the barrier. do. Moreover, the solvent entering the recess due to capillary action remains in the recess even if the parts are randomly treated or placed. According to the method of the present invention, which is different from the conventional solvent bonding method, after assembling a plurality of parts, assembling all the parts, a solvent may be added to each assembled pair of parts to complete the solvent bonding process.

The solvent joint according to the present invention is a pair of plastic members that are overlapped so that the liquid does not leak, and the overlapping part serving as a barrier to prevent fluid (gas or liquid) from flowing in either direction past the end of the concave portion. The end portion between the communicating members is made up of a thinner recessed portion, and at least a permanent solvent bond between the members located at the end of the recessed portion. The members are tubular and one member can accept and overlap the other member. One or both plastic members are made of elastic plastic material. The member which receives another member has an outer edge which forms an annular passage or recess for receiving the end of another overlapping member. The overlapping portions of the members usually converge at an angle of 1 to 10 degrees to form an increasingly recessed end, but the angle is preferably 2 to 6 degrees. The member receiving the other member may have an annular inner structure which is bitten at the end of the inserted annular plastic member, if necessary. In particular, when the inner diameter of the parts to be joined is about the same or the outer plastic member is made of an elastic material, this structure is useful as a stop for limiting the degree to which other members are inserted.

A series of evenly spaced protrusions attached to at least one member are positioned at the inlet of the indentation during solvent injection, and the solvent sealing process maintains the parts in a centered relationship with the inlet at regular intervals. It acts to ensure uniform solvent adhesion around the parts. These protrusions retain the solvent immediately after it is injected and allow the user to see that the proper amount of solvent has been injected. When a suitable amount of solvent is injected, the solvent evaporates and the protrusions dissolve and the protrusions are practically dissolved after the solvent bonding process is completed, so that the plastic material deforms as part of the joint.

The method according to the invention forms two plastic members such that the end leading to the overlapping portion rubs against the increasingly recessed portion in the overlapping portion where the fluid is not leaking, and serves as a barrier to prevent fluid from flowing. And the two members are brought into contact with each other in a sealed state by overlapping portions, and a solvent is injected into the recesses to form a permanent solvent adhesive portion between the two members. One of the parts is in contact with a fluid, such as a liquid (for example, the neck of a plastic bag containing this part of the liquid), and the frictionally sealed part has a liquid flow into the recess, It prevents the occurrence of obstacles and prevents the solvent from entering the place including the liquid and contaminating it after the solvent is injected.

Accordingly, another object of the present invention is to provide a solvent adhesive plastic joint for transporting a fluid such as a medical sterilization liquid used for surgery or for administering to a patient. It is another important object of the present invention to provide the structure of the present invention and realize its advantages. Other objects of the present invention will be apparent from the structure and operation described in detail later, the claims, the drawings and the like.

In FIG. 1a the numeral 10 represents a plastic mold having a junction 11 formed according to the invention. The frame 10 is generally annular in shape and includes a main body portion 12 and a closed portion 13. Frame 10 is used to regulate the flow rate of the medicinal solution and has a float valve 14 (shown in FIG. 1A only) for this purpose.

In order to illustrate one of the various applications of the present invention, the junction 11 is shown in association with the framework 10 in the bonding process. Therefore, the detailed structure of the framework 10 is not very important for correctly and fully understanding the concept of the present invention. Therefore, the following description of the joint is sufficient to explain the joint of the plastic member of various structures within the scope of the present invention.

The junction 11 comprises a pair of plastic members 18, 19 which are engaged to friction in the overlapping portion 20 where the liquid is not leaking (shown in FIG. 4A). There is an increasingly narrow recess 21 leading to the overlapping portion 20 between the two plastic members 18, 19. The overlapping portion 20 acts as a barrier to prevent liquid from passing during or before solvent adhesion formation.

The solvent adhesion part 22 is formed in the recessed part 21 with the edge between the plastic members 18 and 19 by the well-known plastic solvent, such as cyclohexanone and tetra hydrofuran. The term “solvent” as used herein refers to a liquid adhesive that dissolves or softens the plastic material, which is the material of the mold, even when the solvent contains fillers or other components that are not adhesive. It is called a solvent. As such, a solvent or bonding material containing a liquid medium that is a plastic solvent of a mold is considered to be a solvent in the present description.

The overlapping portion 20 acts as a barrier to prevent solvent from flowing through the end of the recess, otherwise the solvent contacts the valve member 14 (which impedes further action in this case), or There may be contact with liquids or other substances outside the part. Even if one of the outlets 12a and 13a for the frame parts 12 and 13 is connected to a place containing a substance such as a liquid (ie, a tube, a bag, a bottle, etc.) before the solvent bonding process, the solvent flows over the end of the recess There is no risk of contaminating the fluid (liquid or gas) inside or within the frame 10, and there is no risk of fluid flowing into the cracks and preventing the formation of effective solvent bonds after the members are frictionally connected.

The plastic members 18 and 19 are tubular. The end 23 of the member 18 is adapted to engage the end 24 of the member 19 in the overlapping portion 20. The end portion 24 of the member 19 receives and overlaps the end portion 23 of the member 18. As shown in FIGS. 4A and 5A, the end portion 24 is immersed along the annular shoulder 25 with the rest of the member 19, and is inserted into the member 19 with the member 18 mounted on the shoulder 25.

The overlapping portion of the receiving member 19 forms an angle of 1 to 20 degrees with respect to the overlapping portion of the member 18 to be inserted, but is preferably in the range of 2 to 6 degrees. Thus, in order to best practice the present invention, it is preferable that the member 18 inside or inserted be inclined 1 to 3 degrees with respect to its axis, and the receiving member 19 is also inclined with respect to its axis by 1 to 3 degrees. As a result, the solvent injection recess has an angle of 2 to 6 degrees.

Since the overlapping portions are formed between the plastic members, these members, in particular the inner member 18 to be inserted, are rigid or semi-rigid such as polystyrene, vinylpropylene polymer, cellulose acetate, cellulose nitrate, acrylic polymer or the like. It should be a rigid plastic material. Of course, other plastics with similar properties that are soluble in solvents are acceptable. Resilient plastics such as plasticized polyvinylchloride may also be used in some cases. This material is particularly suitable when the angle of the recess is near the upper limit of the permissible range.

In practicing the method of the present invention, first, the plastic members are fitted to form a recess in the overlapping portion to pre-sealed the fluid so that no fluid flows, and fluid material such as liquid past the recess is not in contact with the wall of the recess. Don't let that happen. The solvent is then injected into the recess, which spreads out by capillary action to soften the plastic in the recess, and after the solvent evaporates, a permanent bond is formed.

The capillary action also allows the solvent to be retained in the recess, even if the parts are flipped over (after the mouth of the recess is facing down). Thus, during production, after assembling a plurality of parts, even if the solvent is injected into each recess, the solvent does not flow out of the recess even if the assembled parts are positioned in any direction.

Figure 6a shows another method according to the invention the manufacturing method of the junction 111. The junction 111 includes a pair of plastic members 118 and 119 engaged to friction within the overlapping portion 120 where the liquid is not leaking. The tapered concave inlet 121 with the tip X in the outer region is located between the plastic members 118 and 119 leading to the overlapping portion 120. The overlapping portion 120 serves as a barrier that prevents fluid such as a liquid from flowing into the indentation 121 before the solvent bonding is performed, and serves as a barrier that prevents the solvent and the fluid from contacting each other during the solvent bonding. A solvent bonding portion 122 is formed between the plastic members 118 and 119 in the penetration portion 121 near the overlapping portion 120. The junction 111 thus formed is likewise suitable for transporting liquids so that they do not leak and are not contaminated.

As such, the method of the present invention produces a fluid-free joint in two stages. The first step is to temporarily fix the members and form a tight seal that is sealed to prevent liquid leakage. In the second step, the capillary phenomenon is used to inject and retain the solvent on one side of the sealing portion to prevent the fluid from leaking so that the solvent adhesion is performed between the two members. This solvent joint, together with the frictionally arranged members, prevents leakage or contamination of the liquid or other fluid therein. In addition, since the bonding process is performed in two stages, accurate mechanical positioning or alignment of the members can be performed or inspected before bonding. Once the correct mechanical placement is achieved, the members are held in the correct position by the friction force until the solvent is injected and the bonding process is finished.

The number 10 'in FIG. 1B generally represents a parenteral liquid dosing bag having an outlet portion 11'. Outlet portion 11 'comprises a solvent junction 12' (FIG. 7b) formed in accordance with the present invention. The solvent junction is particularly suitable for use in a medicament liquid dosing device to connect parts even if one component (bag in this figure) contains a medicament when the solvent junction is formed.

Outlet portion 11 'includes a tear cap 13', hole cover 14 ', outlet tube or neck 15'. The outlet 15 'is attached to one end of the bag 10 and communicates with the inside of the bag 10'. The hole cover 14 'includes a tubular insert 16' that enters the end of the neck or tube 15 'and ends at membrane 17'. The hole cover 14 'also has a concentric outer edge portion 18' which extends around the insert 16 'and connects with the connecting portion 19'.

The solvent joint 12 'is formed between a pair of plastic members consisting of an outlet tube or neck 15', an outer portion of the aperture cover 14 'or an edge 18' as shown. However, the junction of the outlet portion is illustrated as one of several embodiments of the present invention. Therefore, the solvent bonding described below is also suitable for joining various types of plastic members within the scope of the present invention.

In Figures 4b and 5b, just before the solvent injection and dissolution, the members 15 'and 18' are in close contact so as not to leak fluid along the overlapping annular portion 20 '. The overlapping portion 20 'is in the form of a directly sealed contact between the inner surface of the edge member 18' near the base and the outer surface near the end of the tube member 15 '. The recess 21 'extends from the end of the edge member 18' to the overlapping portion 20 '.

In the illustrated embodiment, the member 18 'is attached with a plurality of uniformly circumferentially arranged protrusions 23'. These protrusions 23 'are pressed against the outer surface of the member 15' and extend apart from each other in parallel with the overlapping portion 20 '. As shown in FIG. 4B, the protrusions 23 'are arranged at an axial distance from one end of the edge portion 18', i.e. near the inlet of the recess, 20 'overlapping portion.

The second overlapping portion 24 'is located between the inner surface of the hole tube 15' (end of tube 15 ') and the outer surface of the base of the insert 16'. Thus, when the hole tube 15 'is inserted into the annular recess of the hole cover 14', the protrusions 23 'of the member 18' are forcibly pressed against the outer surface of the member 15 ', so that the fluid-tight seals 20' and 24 ' Is formed. The protrusions 23 'adjust the shape of the indentation 21' and keep their size uniform throughout the circumference, regardless of where on the circumference the injected solvent is injected after the members are assembled. To spread evenly.

Clearly, the present invention is particularly useful when the two members 15 'and 18', or at least the member 18 ', are made of a resilient plastic material. Any plastic material that can be solvent bonded can be used. For example, polyvinyl fluoride, styrene butadiene, etc. are mentioned. However, many other solvent-adhesive plastic materials with similar properties are known and can be used.

The circumferential edge portion 18 ', which can be considered as a overlapping or acceptable member, has an angle of 1 to 20 degrees with respect to the outer surface of the member 15', in particular having an inner surface that is good to make an angle of 2 to 6 degrees. In other words, in the embodiment of the present invention, the angle formed by the recess 21 'is about 2 to 6 degrees. This allows the solvent to enter well into the overlapping portion 20 'through the recess, and retain the solvent in the recess even if the members are flipped immediately after solvent injection.

The method of joining the members is as follows. First, the members are engaged to friction as shown in FIGS. 2B, 4B, and 5B. Since no solvent has been injected yet and dissolution has not begun, the members can be easily placed in the correct position with each other. When the members are correctly discharged from each other, an overlapping portion 24 'is formed, which acts as a barrier to prevent liquid (or other fluid) from flowing from the bag 10' to the inlet 21 ', so that the liquid wets the surface of the inlet Prevents solvent adhesion from interfering.

The solvent adhesion part 12 'is formed by inject | pouring the solvent 22' into the inlet part of a recess as shown in FIG. 6B. The liquid solvent is spread evenly around the member 15 'in the recess, so as to evenly dissolve the opposing surfaces of the members. The amount of solvent may vary from case to case, but in order to best practice the present invention, an amount of solvent sufficient to surround the protrusion 23 'must be supplied. The protrusion then serves as an instrument to indicate whether a sufficient amount of solvent has been injected.

The liquid solvent 22 'begins to evaporate after injection and begins to dissolve the layer of plastic material that is in direct contact. At the end of the evaporation, the final solvent forming adhesive 12 'is completed. The members are then as shown schematically in FIG. The material contained in the recess is the stocked plastic from the members 14 'and 15'. As such, the junction is a dissolution junction, and indeed the material in the recess is invisible to the plastic members themselves. In the case where the joint is formed by injecting the solvent to the same level or higher than the protrusion 23 ', the protrusion does not maintain a circular shape at the final joint. After acting as a spacer to spread the solvent evenly within the recess, the protrusions dissolve, especially because of their relatively large surface area, becoming part of the stocked material from which the members are dissolved.

The overlapping portion 20 'during evaporation of the solvent prevents the solvent from flowing into the interior through the recess. Thus, the two overlapping portions 20 'and 24' together prevent contact of the liquid (or other mail) in the bag with the injected solvent to form a permanent bond, contaminating the contents in the bag or making the fluid in the bag effective. Do not disturb the formation of the solvent adhesive. After the solvent is injected and evaporated, there is no risk of contamination between the members, and there is a permanent solvent adhesion portion 12 'with no risk of leakage.

As the solvent 22 ', any well-known plastic solvent, such as cyclohexanone and tetrahydrofuran, may be used. The term “solvent” as used herein refers to a liquid adhesive that has the ability to soften or dissolve a plastic material that is the material of the member, and that solvent contains fillers or other components that are not adhesive. This is also called a solvent. As such, a solvent or a bonding material containing a liquid medium that is a solvent of the plastic member will be considered as a solvent in the present description. While the above has been described in detail with respect to an embodiment of the present invention, various modifications may be made without departing from the spirit and scope of the present invention.

Claims (1)

As described herein and shown in the figures, the inclined recesses between the opposite sides of the two plastic members that are received as overlapping portions are frictionally engaged to form a fluidly overlapping portion between the faces of the members. The member is separated by spacers that are newly positioned from the overlapping portion and positioned continuously along the inlet to the recess, at the same time with overlapping between the spacers to form a solvent bond between the members. Two plastics that inject the solvent into the losing portion, the spacers being defined by at least one protrusion in the member, and the step of injecting the solvent injects enough solvent into the indentation to surround the protrusion with the solvent and substantially melt the protrusion. Method of joining members.

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