JP5103090B2 - Gel fluid filling container and squeezing device - Google Patents

Description

  The present invention relates to a container filled with a gel-like fluid such as a caulking agent or an adhesive used for sealing between outer wall materials such as a house, and a squeezing device for discharging the fluid to the outside.

  For example, caulking agent is a sealing material that is injected into gaps and the like that occur in outer wall materials during construction of houses, etc., and is filled as a gel-like liquid like toothpaste, and then dried and hardened after injection. To do. Since the caulking agent is used for sealing between outer wall materials such as houses and is consumed in large quantities, regarding the disposal of the filling container after use, the shape of the filling container after use and the amount of the remaining caulking agent are: This is a major problem in terms of disposal and environmental friendliness.

  By the way, there are the following two types of containers filled with gel fluid.

  One is a method in which a hard cylindrical paper tube is filled with a caulking agent, and is used with a squeezing device that inserts a piston from the opposite side of the discharge port to push out the caulking agent like a water gun.

  The other is to put two sheets of synthetic resin together and bond the surroundings, and fill the gel fluid between the sheets, like a toothpaste tube. It is a structure that squeezes out by hand.

The former filling container has the advantage that the entire caulking agent can be discharged without leaving the contents, and the latter filling container has the advantage that the filling container is not bulky after the caulking agent is discharged.
JP 2003-213925 A

  However, in the former filling container, the paper pipe container after extrusion of the caulking agent has the same volume as before extrusion, which is bulky and has a problem in disposal, and further, the production cost is higher than the latter filling container. There is. In addition, the latter filling container has a problem that the entire contents cannot be squeezed out, and a small amount remains in the vicinity of the discharge port, which not only wastes the contents but also has an environmental impact due to disposal. There was concern.

  There is also a two-component adhesive that uses two types of resin mixed in the field. For this reason, only the former filling container has been used so far, and there has been a problem in the above disposal. .

  The present invention has been made to solve the above problems, and is of one liquid type (consisting of only one kind of fluid) and two liquid types (consisting of two kinds of fluid). The gel-like fluid filling container can discharge almost all the gel-like fluid as the contents, can be discarded without adversely affecting the environment, and is not bulky at the time of disposal, and the filling container It is an object of the present invention to provide a squeezing device that efficiently discharges a gel fluid.

  In order to solve the above problems, the invention according to claim 1 is directed to a gel-like fluid-filled container in which a container body is made of a synthetic resin sheet material with an aluminum foil sandwiched therebetween. The discharge collar is fixed, and the discharge collar is characterized in that a locking portion for mounting a nozzle for discharging the internal gel fluid is formed.

  According to a second aspect of the present invention, in the first aspect, a discharge port for discharging the gel fluid is formed in the discharge collar, and the discharge port is sealed with a synthetic resin sheet material sandwiching an aluminum foil. It is characterized by that.

  According to a third aspect of the present invention, in the first or second aspect, thin fins are formed on both sides of the discharge collar.

  According to a fourth aspect of the present invention, in the first, second, or third aspect, the base portion of the nozzle is fitted into the discharge port of the discharge collar.

  The invention according to claim 5 is formed by filling two container bodies made of a synthetic resin sheet material with an aluminum foil sandwiched between the container bodies with separate gel fluids and integrally connecting the respective discharge ports. In a gel-like fluid-filled container, a flat discharge color is fixed to the discharge port of the gel solution of each container body, and both discharge colors are superposed and joined together, and at the tip of each discharge color. Has a discharge end portion having a substantially semicircular cross section, and when the discharge collars are combined, the discharge end portion is formed in a cylindrical shape.

  The squeezing device for a gel-like fluid filling container according to claim 6 is a gel-like fluid filling container having a container body made of a synthetic resin sheet material, and a flat discharge collar is fixed to the discharge port of the container body. The discharge collar fixes the front and rear ends of a gel-like fluid-filled container in which a locking portion for mounting a nozzle for discharging the gel-like fluid inside is fixed, and the container body is opposite to the discharge port. A rotating roller that crushes from the side and discharges an internal gel fluid is provided.

  According to the first aspect of the present invention, the container body is made of a synthetic resin sheet material with an aluminum foil sandwiched therebetween, and a flat discharge collar is fixed to the discharge port of the container body. Since the engaging part for mounting the nozzle for discharging the gel-like fluid inside is formed, the volume of the container body decreases as the remaining amount of the gel-like fluid decreases as the gel-like fluid is squeezed out. When the gel fluid is squeezed to the maximum, the discharge collar is formed flat, so there is almost no space between the container body and the discharge collar, and there is almost no remaining gel fluid. Therefore, the caulking agent in the container body can be used up almost without waste. In addition, since the container main body is comprised with the synthetic resin sheet material which pinched | interposed the aluminum foil, the infiltration of the water | moisture content in air inside is interrupted | blocked.

  Further, since the container body is made of a synthetic resin sheet material and the discharge collar is formed flat, the entire container becomes flat after the gel fluid is discharged. Therefore, even if a large amount of gel fluid is used and a large number of empty containers are accumulated, it is not bulky at the time of disposal and does not adversely affect the disposal environment.

  According to the invention of claim 2, since the discharge port of the discharge collar is further sealed by the synthetic resin sheet material sandwiching the aluminum foil, the sheet is opened with an appropriate rod-shaped jig to open the discharge port. It is only necessary to break the material, and it is not necessary to remove the cap as in the conventional case, so that the opening can be easily performed.

  According to the invention of claim 3, since the thin fins are formed on both sides of the discharge collar, the two sheet materials are welded to the front and back surfaces of the fin. Good adhesion.

  According to the fourth aspect of the present invention, since the base portion of the nozzle is inserted into the discharge port of the discharge collar, all the gel-like fluid pushed out from the container body into the discharge collar is contained in the nozzle. It enters and remains in the nozzle. Since this nozzle can be used in another gel-like fluid filled container, the residual fluid in the nozzle is then used. Therefore, the caulking agent in the container body can be used up almost without waste.

  According to the invention of claim 5, a flat discharge color is fixed to the discharge port of the gel-like solution of each container body, and both discharge colors are superposed and joined together. A discharge end portion having a substantially semicircular cross section is formed at the tip of the nozzle, and when the two discharge collars are combined, the discharge end portion is formed in a cylindrical shape. A known static mixer is attached to the discharge end portion. The two liquids discharged from the discharge end can be mixed and squeezed out.

  Further, as the caulking agent is squeezed out, the volume of the container body decreases as the remaining amount of the caulking agent decreases. When the caulking agent is fully squeezed to the maximum, the discharge collar is formed flat, so there is almost no space between the container body and the discharge collar, and there is almost no remaining coking agent. Therefore, the caulking agent in the container body can be used up almost without waste.

  Moreover, since the container body is made of a synthetic resin sheet material and the discharge collar is formed flat, the entire container becomes flat after the caulking agent is discharged. Therefore, even if a large amount of caulking agent is used and a large number of empty containers are accumulated, the caulking agent is not bulky at the time of disposal and does not adversely affect the disposal environment.

  According to the sixth aspect of the present invention, when the contents are squeezed out by the rotating roller with the front and rear ends of the above-described filling container A being fixed, the discharge collar is formed flat, so that the remaining amount is almost It can be squeezed to a state where it is not discharged. Therefore, it is the least wasteful, efficient, and can be squeezed easily.

  Moreover, since the front and rear ends of the filling container are fixed, the position of the discharge outlet of the filling container through which the contents are discharged does not change throughout the squeezing operation. Therefore, since the discharge position of the contents is always stable at the same position, the work of applying the contents can be performed efficiently.

[Embodiment 1]
As a first embodiment of the present invention, a filling container of a one-component gel fluid will be described as a filling container of a caulking agent.

  In FIG. 1 and FIG. 2, the symbol A indicates a caulking agent filling container. The filling container A is composed of a container body 1 and a discharge collar 2.

  As shown in FIG. 2, the container body 1 is configured by welding two sheets of synthetic resin sheet material 3 with an aluminum foil interposed therebetween. That is, corresponding sides of two rectangular sheet materials having the same shape are overlapped with each other, and the long side portion 4 is heat-welded with a constant width along the end portion. Further, the discharge collar 2 is fixed to the central portion of the end of one short side 5a.

  As shown in FIG. 4, the discharge collar 2 is formed by forming an elliptical discharge port 6 at the center of a hexagonal short cylindrical color body 2 a having a flat outer shape with a synthetic resin such as polypropylene. Hole-shaped recesses 7 for mounting the nozzles are formed on both sides of each of these, and locking jaws 8 are formed to project from the inner walls of these recesses 7. The opening end side of the locking jaw 8 is tapered. Further, thin fins 10 are formed on both sides of the discharge collar 2.

  A cap seal 11 made of a synthetic resin sheet or an aluminum thin film sandwiching an aluminum foil for sealing the discharge port 6 is adhered or welded to the back surface of the discharge collar 2.

  In the above configuration, the discharge collar 2 is sandwiched between the short side portions 5a of the two sheet materials 3, and both the front and back surfaces of the discharge collar 2 are welded by the short side portions 5a of the front and back sheet materials 3, respectively. . The short side portion 5a that is in direct contact is also welded obliquely. Since the thin fins 10 are formed on both sides of the discharge collar 2 and the two sheet materials 3 are welded to the front and back surfaces of the fin 10, the adhesion between the discharge collar 2 and the sheet material 3 is good. Thereby, only the bottom part of the container main body 1 is opened. Therefore, the caulking agent is filled from the open portion, and after filling, the bottom portion 5b is welded and sealed to seal the caulking agent inside the filling container A.

  Next, the code | symbol 12 shows a nozzle. The nozzle 12 is made of a synthetic resin, and is composed of a base body portion 13 and a throttle portion 14 on the tip side thereof. The body portion 13 is formed in a size and shape that can be fitted inside the discharge port 6 of the discharge collar 2, the throttle portion 14 at the tip thereof is narrowed so as to be tapered, and the tip is formed to be slightly sharp and rounded. A discharge hole 9 for the caulking agent is formed at the end portion with a tinge. Engaging convex portions 15 are formed around the body portion 13. The distance between the base end of the body portion 13 and the engaging convex portion 15 is formed to be the same as the length of the discharge port 6 of the discharge collar 2.

  A locking piece 16 that can be inserted into the recess 7 of the discharge collar 2 is formed on both sides of the nozzle 12, and a locking hole that can be locked to the locking jaw 8 of the discharge collar 2 is formed at the tip of the locking piece 16. 17 is formed.

  In the above configuration, when the caulking agent in the filling container A is discharged, first, the cap seal 11 at the bottom of the discharge collar 2 is broken with an appropriate bar-shaped jig to open the discharge port 6. As shown in FIGS. 2 and 3, the body of the nozzle 12 is inserted in the body 13 of the nozzle 12 into the discharge port 6 and the engaging pieces 16 on both sides are inserted into the recesses 7 on both sides of the discharge collar 2. At the same time that the engaging projection 15 of the portion 13 engages with the opening edge of the discharge port 6, the locking piece 16 is once deformed inward by its elasticity when engaged with the locking jaw 8. When 17 fits into the locking jaw 8, it returns to its original shape. As a result, the nozzle 12 cannot be inserted any more and cannot be pulled out by the engagement of the engagement convex portion 15 and the engagement of the engagement hole 17, and the engagement jaw 8 is inserted into the engagement hole 17. Is held in a locked state.

  After the nozzle 12 is mounted on the discharge collar 2, the inner caulking agent is discharged from the discharge hole 9 at the tip of the nozzle 12 through the discharge port 6 by squeezing the container body 1. When the caulking agent has been squeezed out, the locking piece 16 of the nozzle 12 is bent inward with a finger, the locking between the locking hole 17 and the locking jaw 8 is released, and the nozzle 12 is extracted by pulling it outward. Can do. The nozzle 12 can be reused for other containers.

  As the caulking agent is squeezed out, the volume of the container body 1 decreases as the remaining amount of the caulking agent decreases. When the caulking agent is squeezed to the maximum, the discharge collar 2 is formed flat, so that there is almost no space between the container body 1 and the discharge collar 2, and there is almost no remaining caulking agent. Further, all the caulking agent transferred from the container body 1 into the discharge collar 2 remains in the nozzle 12. Therefore, the caulking agent in the container body 1 can be used up almost without waste.

  Further, since the container body 1 is composed of a synthetic resin sheet material 3 and the discharge collar 2 is formed flat, the entire container becomes flat after the caulking agent is discharged. Therefore, even if a large amount of caulking agent is used and a large number of empty containers are accumulated, the caulking agent is not bulky at the time of disposal and does not adversely affect the disposal environment.

  Next, when the fluid inside the gel fluid filling container is discharged, the squeezing device C shown in FIGS. 5 and 6 is preferably used. That is, the squeezing device C is composed of a device main body 31, a squeezing mechanism 38, and a drive mechanism thereof.

  A grip 33 for gripping the container squeezing device is formed on the device main body 31, and a support plate 32 for supporting the filled container A is formed so as to protrude forward. An opening 34 along the longitudinal direction of the filling container A supported on the support plate 32 is formed in the central portion of the support plate 32, and the inner edges on both sides of the opening 34 extend in the longitudinal direction of the opening 34. Along the guide groove 35 is formed.

  A slider 36 slidable along the longitudinal direction of the support plate 32 is provided. A ridge (not shown) is formed on both side edges of the slider 36, and the slider 36 is engaged with the guide grooves 35 formed on both side edges of the opening 34 of the support plate 32. The apparatus main body 31 is supported so as to be slidable.

  A squeezing mechanism 38 that squeezes the filling container A placed on the support plate 32 is provided at the upper front end of the slider 36. The squeezing mechanism 38 is configured by a lower roller 39 and an upper roller 41 that are arranged facing each other in the vertical direction so as to squeeze the filling container A from the vertical direction. Each of the rollers 39 and 41 is a rotating roller, and is rotatably supported in the upper frame 40 and the lower frame 42 by a shaft 43 orthogonal to the sliding direction of the slider 36, and the upper frame 40 is located on the upper front end of the slider 36. It is fixed. The lower frame 42 can be opened and closed with respect to the upper frame 40.

  The apparatus main body 31 is provided with a fixing means for fixing the filling container A. That is, on the upper surface of the front and rear end portions of the apparatus main body 31, an engagement piece 53 that can be inserted inside the L-shaped locking piece 16 of the nozzle 12 at the front portion of the filling container A and the rear portion 25 side of the filling container A are formed. A pressing member 26 for fixing the protruding edge 46 to the apparatus main body 31 is formed. One pair of these is provided. The pressing member 26 is provided so as to be movable up and down with respect to the apparatus main body 31 and can be locked at the lower part.

  A fixed protruding edge 46 is formed along the rear edge of the rear portion 25 which is sealed and formed in a flat shape at the rear of the filling container A, and this protruding edge 46 is formed on the main body of the apparatus. The rear portion 25 side of the filling container A is fixed to the apparatus main body 31 by being engaged with the pressing member 26 of 31. A portion close to the rear portion 25 of the filling container A, the rear portion 25 of which is fixed to the apparatus main body 31 by the pressing member 26, is sandwiched between the lower roller 39 and the upper roller 41, and the filling container A is moved to the rear portion 25 by moving the slider 36 forward. It is crushed sequentially from the side toward the front.

  Next, the device main body 31 is provided with a drive mechanism that drives the squeezing mechanism 38 by sliding the lower roller 39 and the upper roller 41 of the squeezing mechanism 38 forward along the support plate 32. This drive mechanism is opposed to a large number of teeth 47 formed along the longitudinal direction of the slider 36 on the lower surface of the slider 36 and the grip 33 formed on the apparatus main body 31 and meshed with the teeth 47. And a trigger 49 that is rotatably supported by the apparatus main body 31.

  A concave groove 48 is formed on the lower surface side of the slider 36 along the longitudinal direction. A large number of sawtooth-like teeth 47 are formed along the longitudinal direction at the bottom of the concave groove 48. A claw piece 51 that can mesh with a tooth 47 formed on the lower surface of the slider 36 is swingable at an upper end portion of a trigger 49 that is provided in the apparatus main body 31 so as to be rotatable about a support shaft 50. It is attached. The trigger 49 is always urged from the grip 33, and the claw piece 51 is biased by a spring (not shown) so that the front end meshes with the teeth 47 of the slider 36.

  When attaching the filling container A to the squeezing device C, first, the upper roller 41 is opened, and the end of the filling container A on the rear part 25 side is arranged on the upper part of the lower roller 39 so that the protruding edge on the rear part 25 side of the filling container A The portion 46 is engaged with the pressing member 26 of the apparatus main body, and the filling container A is fixed to the apparatus main body 31. Further, the engagement piece 53 at the front end of the support plate 32 is engaged with the inside of the L-shaped locking piece 16 of the nozzle 12 at the front portion of the filling container A, and the filling container A is fixed to the upper surface of the support plate 32. Attach with. Thereafter, the lower frame 42 is closed and fixed to the upper frame 40 side so that the upper roller 41 faces the lower roller 39. As a result, the rear portion 25 of the filling container A is sandwiched between the upper roller 41 and the lower roller 39.

  Next, when squeezing out the contents (gel fluid) of the filling container A, the grip 33 is grasped, the nozzle 12 of the filling container A is applied to a necessary part, and the trigger 49 is pulled. The trigger 49 rotates about the support shaft 50 and moves forward with the claw piece 51 at the upper end engaged with the teeth 47 of the slider 36 to move the slider 36 forward. Since the rear portion 25 side of the filling container A is fixed to the rear portion of the apparatus main body 31, when the slider 36 moves forward, the squeezing mechanism 38 formed at the front end portion of the slider 36 moves forward, and the upper portion The roller 41 and the lower roller 39 roll and move forward while squeezing and crushing the filling container A, and the crushing part by the upper roller 41 and the lower roller 39 is gradually moved forward. At this time, the filling container A is squeezed and the contents are discharged from the nozzle 12.

  After that, when the force on the trigger 49 is released, the trigger 49 returns to the original position again by the spring force. At this time, the claw piece 51 swings away from the slider teeth 47 and moves backward, so that the slider 36 moves. Does not move backwards. When the trigger 49 is pulled again, the claw piece 51 engages with the teeth 47 on the rear side of the slider 36 to move the slider 36 forward, and the diaphragm mechanism 38 by the upper roller 41 and the lower roller 39 further moves forward. The filling container A is squeezed and the contents are squeezed out from the nozzle 12 and discharged.

  By repeating the above operation, the squeezing mechanism 38 of the filling container A gradually moves forward, and the contents in the filling container A can be gradually squeezed out. Finally, as shown in FIG. 7, the discharge collar 2 of the filling container A can be squeezed out to the last minute. Since the filling container A is made of a synthetic resin sheet with an aluminum foil sandwiched therebetween, the filling container A actually does not bend as much as in FIG.

  As described above, when the contents are squeezed out by the rollers 39 and 41 with the front and rear ends of the filling container A being fixed to the front and rear portions of the apparatus main body 31, the discharge collar 2 is formed flat. It can be squeezed and discharged to a state where there is almost no amount. Therefore, it is the least wasteful, efficient, and can be squeezed easily.

  Moreover, since the front and rear ends of the filling container A are fixed to the front and rear parts of the apparatus main body 31, the position of the nozzle 12 of the filling container A from which the contents are discharged does not change throughout the squeezing operation. Therefore, since the discharge position of the contents is always stable at the same position, the work of applying the contents can be performed efficiently.

  The driving mechanism that drives the aperture mechanism is not limited to the above-described form. A pinion rack mechanism may be used, or another known mechanism may be used.

[Embodiment 2]
Next, as a second embodiment, a fluid-filled container B using a gel fluid as a two-component adhesive will be described with reference to FIGS.

  Adhesives include not only one-component adhesives based on silicon-based or urethane-based resins, but also two-component adhesives that use epoxy-based, urethane-based, and acrylic-based resins mixed on site. The two-liquid type gel fluid filling container B of the present embodiment is basically a combination of two one-pack type filling containers A in which the discharge collar 2 of the main body 1 is changed as shown in FIG. It is comprised by the aspect.

  That is, as shown in FIG. 8, the filling container B is configured by bonding the first filling container B1 and the second filling container B2, each having the same shape, in the manner described below.

  The discharge collars 2 of the first filling container B1 and the second filling container B2 include fins 10 as in the case of the one-component type discharge collar 2 as shown in FIGS. A section obtained by cutting a plane is a trapezoidal collar body 2a with a semi-cylindrical discharge portion 20 extending from the tip of the collar body 2a. As shown in FIG. One end 4a of the portion 4 bends to the right or left, and the collar body 2a is sandwiched between the short side portions 5a at the tip thereof and heat-welded. A cap seal (not shown) is applied to the bottom of each discharge collar 2. 21 is a male screw.

  Next, the first filling container B1 and the second filling container B2 are obtained by adhering both the discharge collars 2 at the plane portion 22 so that the collar body 2a has a hexagonal shape and the discharge part 20 has a cylindrical shape. A type of filling container B is constructed. Only the short side 5a on the bottom side of the container body 1 is opened. Each of the open portions is filled with a gel-like liquid for adhesive, and after filling, the bottom portion 5b is welded and sealed. Thereby, the filling container B in which the caulking agent is sealed inside the first filling container B1 and the second filling container B2 is completed. Since the first filling container B1 and the second filling container B2 are divided into left and right as shown in FIG. 11, the filling container B does not become thick as a whole.

  Next, the code | symbol 23 shows a static mixer (refer FIG. 8). The static mixer 23 is a well-known cylindrical member formed so that a complicated intricate passage is formed inside, and the fluid entering independently from the base is mixed while passing through the internal passage.

  In the above configuration, when the two liquids in the filling container A are discharged, first, the cap seals at the bottoms of the discharge collars 2 of the first filling container B1 and the second filling container B2 are broken to open the discharge port 6. Then, the base of the static mixer 23 is fitted to the tip of the cylindrical discharge part 20, and the female screw of the nut 24 is screwed onto the male screw 21 of the discharge part 20 and attached.

  After mounting the static mixer 23 on the discharge collar 2, the inner gel-like liquid is discharged from the discharge collar 2 and the discharge port 20 by squeezing the container body 1 of the first filling container B1 and the second filling container B2. 6 and discharged into the static mixer 23. The two liquids that have independently entered the static mixer 23 are mixed while passing through the internal passage and applied to the object to be bonded. When the two liquids have been squeezed out, the static mixer 23 is removed or the entire static mixer 23 is discarded.

  As described above, the volume of the container main body 1 decreases as the adhesive amount decreases as the adhesive is squeezed out. When the adhesive is squeezed to the maximum, the discharge collar 2 is formed flat, so there is almost no space between the container body 1 and the discharge collar 2 and there is almost no remaining adhesive. Therefore, the adhesive in the container body 1 can be almost used up.

  Further, since the container main body 1 is made of a synthetic resin sheet material 3 and the discharge collar 2 is formed flat, the entire container becomes flat after the adhesive is discharged. Therefore, even if a large amount of adhesive is used and a large number of empty containers are accumulated, it is not bulky at the time of disposal and does not adversely affect the disposal environment.

  The outer shape of the color main body 2a of the discharge collar 2 is not limited to a hexagonal shape. For example, it may be an ellipse, or may have a continuous corner and curved surface.

  Moreover, the thing of the said embodiment can be efficiently squeezed out by the squeezing apparatus provided with the roller similar to the above-mentioned.

  Note that the rotating rollers are not limited to the two arranged on the upper and lower sides. A configuration in which only one piece is used may be used.

  Further, the means for fixing the filling container to the squeezing device is not limited to that shown in the figure. Of course, other fixing means may be used.

The perspective view of the gel-like fluid filling container and nozzle which concern on 1st Embodiment The perspective view which shows the state which attached the nozzle to the said gel-like fluid filling container. Sectional drawing which follows the XX line of FIG. Perspective view of discharge color Vertical section of squeezing device Exploded view of the main part of the squeezing device Sectional drawing of the principal part which shows the final state of squeezing The perspective view of the gel-like fluid filling container and static mixer which concern on 2nd Embodiment (A) (b) is a perspective view of the front side and the back side of the discharge collar The perspective view which decomposed | disassembled the said gel-like fluid filling container into the 1st, 2nd filling container The top view of the principal part of the above-mentioned gel fluid filling container

Explanation of symbols

A, B Filling container 1 Container body 2 Discharge color 3 Sheet material 12 Nozzle

Claims (6)

In a gel-like fluid-filled container composed of a synthetic resin sheet material with an aluminum foil sandwiched between the container body, a flat discharge collar is fixed to the discharge port of the container body. A gel-like fluid-filled container , wherein a locking part having a locking jaw for mounting a nozzle for discharging a gel-like fluid is formed, and the nozzle has a locking hole .   The gel-like fluid-filled container according to claim 1, wherein a discharge port for discharging the gel fluid is formed through the discharge collar, and the discharge port is sealed with a synthetic resin sheet material sandwiching an aluminum foil. .   The gel fluid filling container according to claim 1 or 2, wherein thin fins are formed on both sides of the discharge collar.   The gel fluid filling container according to claim 1, 2 or 3, wherein the base of the nozzle is fitted into the discharge port of the discharge collar. In a gel-like fluid-filled container formed by filling two container bodies composed of synthetic resin sheet materials with separate gel-like fluids and integrally connecting the respective discharge ports,
A flat discharge collar is fixed to the discharge port of the gel solution of each container body, and both discharge collars are superposed and joined together, and the tip of each discharge collar has a substantially semicircular cross section. A gel-like fluid-filled container, wherein a discharge end is formed in a cylindrical shape when a discharge end is formed and the discharge colors are combined.   In a gel-like fluid-filled container composed of a synthetic resin sheet material with an aluminum foil sandwiched between the container body, a flat discharge collar is fixed to the discharge port of the container body. While fixing the front and rear ends of the gel-like fluid-filled container in which the locking portion for mounting the nozzle for discharging the gel-like fluid is formed, the container body is crushed from the opposite side of the discharge port so that the gel-like fluid inside is A squeezing device for a gel-like fluid-filled container, comprising a rotating roller for discharging.

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