JP4557680B2 - Drainage hose and manufacturing method thereof - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a flexible synthetic resin drainage hose suitable for drainage of a washing machine, a dishwasher, and the like, and a method for manufacturing the same.

  As a synthetic resin drainage hose having flexibility, conventionally, for example, as described in Patent Document 1, as shown in FIG. 6, a soft synthetic resin in which an inner peripheral surface is formed on a smooth surface over its entire length. The synthetic resin reinforcing core material 22 is spirally wound around the outer peripheral surface of the resin inner pipe 21 at a constant pitch, and the synthetic resin reinforcing core material 22 is entirely covered so as to cover the entire surface. A structure in which a soft synthetic resin outer tube 23 is integrally layered on the outer peripheral surface of a soft synthetic resin inner tube 21 is widely known.

In addition, as described in the above-mentioned patent document, the synthetic resin drainage hose is produced at a constant pitch while polymerizing and welding a semi-molten soft synthetic resin strip on the molding rotating shaft. Thus, the inner tube 21 is formed by spirally winding, and a synthetic resin reinforcing core material 22 is spirally wound on the inner tube 21 and integrally welded to the outer peripheral surface of the inner tube 11, and further, the soft synthetic A reinforcing core material 22 is obtained by spirally winding a semi-molten soft synthetic resin belt material made of the same synthetic resin as the resin belt material material on the inner tube 21 with a constant pitch through the spirally wound reinforcing core material. The outer tube 23 is formed in close contact with the outer peripheral surface of the inner tube 21 without any gap.
JP 2002-286172 A

However, when the synthetic resin drainage hose is curved, a tensile force acts in the length direction on the outer peripheral wall portion bent in a convex arc shape, and the length on the inner peripheral wall portion side bent in a concave arc shape. Although the compressive force acts in the direction, and the inner tube 21 and the outer tube 23 also have a difference in the magnitude of the tensile force and compressive force, the inner peripheral surface of the outer tube 23 as described above, From the outer peripheral surface of the reinforcing core member 22 wound in a spiral shape to the outer peripheral surface of the inner tube 21 exposed between the spiral winding portions 22a, 22a adjacent to each other in the length direction of the hose in the reinforcing core member 22. The inner tube 21 and the outer tube 23 have to be bent integrally because they are stacked in close contact with each other without a gap, and the resistance to bending increases and flexibility decreases. When used as a drain hose for washing machines and dishwashers, the degree of freedom of piping is impaired. Selfishness was also there is a problem that becomes worse used with.

  Further, the outer tube 23 has a spirally wound portion 22a, with the tube wall portion between the adjacent spirally wound portions 22a, 22a of the reinforcing core member 22 spirally wound on the inner tube 21 being in close contact with the outer peripheral surface of the reinforcing core member 22. Since the inner peripheral surface of the inner tube 21 exposed at 22a is entirely welded to the outer peripheral surface of the inner tube 21, the tube wall portion 23a of the outer tube 23 between the adjacent spirally wound portions 22a and 22a is a hose. The spiral groove 24 is deeply curved toward the inner diameter direction of the spiral groove 24. Accordingly, even if dust adheres to and accumulates in the spiral groove 24, the groove of the spiral groove 24 may be wiped off with a rag or the like. It becomes difficult to wipe down to the bottom, and the adhesion of the dust and the like not only impairs the appearance but also may cause the hose to be bent further.

  The present invention has been made in view of the problems as described above, and the object of the present invention is to exhibit good flexibility and to wipe off dust and the like adhering to the surface easily and reliably. In addition, another object of the present invention is to provide a synthetic resin drainage hose that is easy to manufacture and suitable for mass production, and a method for manufacturing the same.

In order to achieve the above object, the drainage hose of the present invention is synthesized with the outer peripheral surface of the inner tube made of soft synthetic resin having the inner peripheral surface formed into a smooth surface over the entire length as described in claim 1. Drainage formed by spirally winding a resin reinforcing core material and integrally forming an outer tube made of the same soft synthetic resin on the soft synthetic resin inner tube via the reinforcing core material A synthetic resin reinforcing core is spirally wound on a soft synthetic resin inner tube with a predetermined pitch, while a soft synthetic resin outer tube is a semi-molten soft material having a certain width. A synthetic resin strip is spirally wound on one side of the preceding strip member while the opposite sides of the following strip are overlapped, and the inner periphery is in contact with the outer peripheral surface of the reinforcing core together are integrally fixed to the face portion on the outer peripheral surface of the reinforcing core, the reinforcing core Presence of air gap pipe wall portion of the outer tube on between the spirally wound portions adjacent in the length direction of the hose, the inner peripheral surface thereof with respect to the outer circumferential surface without close contact with the outer peripheral surface of the inner tube in Thus, the structure is formed by a curved portion that curves inward.

The invention according to claim 2 is a method for manufacturing the drainage hose, which is a belt-shaped material portion that follows a belt-shaped material portion made of a soft synthetic resin in a semi-molten state on a molding rotating shaft and continues on one side of the belt-shaped material portion. The inner pipe is formed by spirally winding the opposite side parts of the inner pipe and welding them together, and a synthetic resin reinforcing core is formed on the outer peripheral surface of the inner pipe at a predetermined pitch. Spirally wound and integrally welded to the outer peripheral surface of the inner tube, and further, a strip of soft synthetic resin is placed on one side of the preceding strip-shaped material portion via the reinforcing core material on the inner tube. while by overlapping opposite sides of the timber portion is integrally welded to face the outer peripheral surface portions of Rutotomoni reinforcing core member is welded integrally with the outer peripheral surface of the reinforcing core material, and, of the hose in the reinforcing core The inner circumferential surface of the strip-shaped material portion between the spiral winding portions adjacent in the length direction And forming an outer tube by winding formed while spirally curved portion spaced from the outer circumferential surface without close contact with the outer peripheral surface of the pipe.

According to the first aspect of the present invention, in the synthetic resin drainage hose having flexibility, the outer tube is integrally provided via the synthetic resin reinforcing core spirally wound on the soft synthetic resin inner tube. The outer tube formed by spirally winding a strip of soft synthetic resin on the inner tube has an inner peripheral surface portion in contact with the outer peripheral surface of the reinforcing core spirally wound on the inner tube. The tube wall portion between adjacent spirally wound portions is gently curved toward the outer peripheral surface without closely contacting the inner peripheral surface with the outer peripheral surface of the inner tube. Since a space is provided between the inner peripheral surface of the tube wall portion and the outer peripheral surface of the inner tube formed in the curved portion, when this drainage hose is curved, the outer peripheral wall portion bent into a convex arc shape has a length. The outer tube in the outer peripheral wall portion where the tensile force acts in the direction but the largest tensile force acts The inner peripheral wall portion bent in a concave arc shape in which the compressive force acts in the length direction while the inwardly curved tube wall portion can absorb the tensile force while deforming in a direction in which it is tensioned with respect to the inner tube In the inner peripheral wall portion where the greatest compressive force acts, the inner wall portion of the inner tube that is curved inwardly separates from the inner tube while further increasing the degree of curvature toward the outer peripheral surface of the inner tube. It can be bent and deformed to reliably absorb the compressive force.

  Therefore, the drainage hose can be smoothly bent without being partially buckled, and the flexible core has a high pressure resistance even though the reinforcing core material spirally wound around the outer peripheral surface of the inner tube. When used as a drainage hose for a washing machine, dishwasher, etc., the degree of freedom of piping is increased and piping can be easily performed even in a narrow place and the usability is improved.

  Further, as described above, the outer tube is formed in this manner without bringing the inner peripheral surface into close contact with the outer peripheral surface of the inner tube in the reinforcing core material spirally wound on the inner tube. Since the spiral groove formed by the curved portion is shallow because it is formed in a curved portion that is gently curved toward the outer peripheral surface, when dust adheres to and accumulates in the groove, a dust cloth, etc. Can be easily and reliably wiped off, and can maintain a clean and hygienic appearance.

Further, according to the method for manufacturing a drain hose, as described in claim 2, a semi-molten soft synthetic resin strip is succeeded on one side of the preceding strip member on the rotating shaft. An inner pipe is formed by spirally winding the overlapping side portions of the strip-like material part and welding them together, and a synthetic resin reinforcing core is placed on the outer peripheral surface of the inner pipe at a predetermined pitch. Then, spirally wound and integrally welded to the outer peripheral surface of the inner pipe, and further, a soft synthetic resin strip is passed over the inner pipe via the reinforcing core on one side of the preceding strip section. in by superposing opposite sides of the strip material portion while integrally welded to face the outer peripheral surface portions of Rutotomoni reinforcing core member is welded integrally with the outer peripheral surface of the reinforcing core material, and said reinforcing core member The strip material part above the spiral winding part adjacent to the length direction of the hose Since the outer tube is formed by spirally winding while forming a curved portion spaced from the outer peripheral surface without being in close contact with the outer peripheral surface of the inner tube, the outer tube and the inner tube It is possible to easily and continuously manufacture a long flexible drainage hose in which a space is formed between the opposing surfaces without the opposing surfaces being in close contact with each other, and in the manufacturing process in this length direction. By cutting the continuous drainage hose at predetermined intervals, a highly flexible drainage hose having a certain length can be efficiently mass-produced, and an inexpensive drainage hose can be provided.

  Next, a specific embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a longitudinal side view of a flexible synthetic resin drainage hose A, and the inner peripheral surface has the same diameter over the entire length. An inner tube 1 made of a soft synthetic resin formed on a smooth surface of the inner tube, a reinforcing core material 2 made of a synthetic resin spirally wound around the outer peripheral surface of the inner tube 1 at a predetermined pitch, The inner peripheral surface portion that is in contact with the outer peripheral surface of the reinforcing core member 2 is integrally fixed to the outer peripheral surface of the reinforcing core member 2 while the inner tube 1 is covered over the entire length through the reinforcing core member 2. Of the outer tube 3 made of a soft synthetic resin, which is in a state of being stretched between the spiral spiral portions 2a and 2a adjacent to each other in the length direction of the hose in the reinforcing core 2. Each tube wall portion 3a has an inner periphery on the outer peripheral surface of the tube wall portion 1a of the inner tube 1 exposed between the spirally wound portions 2a, 2a of the reinforcing core 2. The inner wall 1 is gently curved inwardly toward the outer peripheral surface of the tube wall portion 1a of the inner tube 1, and the tube wall portion 3a of the outer tube 3 is bent from the outer peripheral surface of the tube wall portion 1a of the inner tube 1 A space 4 is provided between the tube wall portions 1a and 3a with the inner peripheral surface being separated.

  Therefore, the outer tube portion fixed integrally to the outer peripheral surface of the reinforcing core member 2 is formed in the spiral ridge portion 3b, and the tube wall connected to the adjacent spiral ridge portions 3b, 3b adjacent to each other. The portion 3a has a shape that hangs gently in a concave arc shape from between the spiral ridges 3b, 3b toward the outer peripheral surface of the inner tube 1, and this concave arc-shaped tube wall portion 3a makes the hose longer. A shallow spiral groove 5 having a continuous depth in the direction is formed.

  The inner tube 1 and the outer tube 3 are made of the same soft synthetic resin, for example, an olefin resin such as polyethylene, polypropylene, EVA resin, or a soft synthetic resin such as vinyl chloride resin. The thickness of the outer tube 3 is made thinner than that of the inner tube 1 so that the flexibility and flexibility of the outer tube 3 are better than those of the inner tube 1. The reinforcing core 2 is a synthetic resin harder than the soft synthetic resin forming the inner tube 1 and the outer tube 3, for example, a synthetic resin having appropriate elasticity and hardness such as polyethylene, polypropylene, and hard vinyl chloride. The cross section is formed in a circular or elliptical shape. Then, the inner tube 1 is spirally wound around the outer peripheral surface of the inner tube 1 at substantially the same pitch as the diameter (long diameter in the case of an ellipse), and the outer peripheral surface of the inner tube 1 is integrally fixed to the inner peripheral surface.

  Further, the end 6 that becomes the connection port of the drainage hose A has an inner diameter that is the same as the inner diameter of the inner tube 1 and an outer diameter that is substantially equal to the outer diameter of the spiral protrusion 3b of the outer tube 3 It is formed at a slightly small diameter thick end. Specifically, the end portion of the inner tube 1 is formed thick so that the inner diameter is the same and the outer diameter is larger, and the outer peripheral surface thereof is closely integrated with the inner peripheral surface of the outer tube 3. In addition, the diameter of the reinforcing core material 2 is reduced to a thin diameter line, and the small diameter reinforcing core material 2 ′ is embedded in the thick end portion 6.

  The synthetic resin drainage hose A configured as described above connects the above-mentioned thick connection end 6 to these drainage ports, for example, for draining a washing machine or for draining a dishwasher installed in a kitchen. Used in the state At this time, as shown in FIGS. 3 and 4, when the drainage hose is curved, the outer peripheral wall portion of the hose that bends in a convex arc shape is subjected to a tensile force in its length direction and bends in a concave arc shape. In the inner peripheral wall portion of the hose, a compressive force acts in the length direction thereof, but the opposing surfaces of the inner tube 1 and the outer tube 3 are not in close contact with each other, and adjacent spiral winding portions in the reinforcing core member 2 2a and 2a are spaced apart from each other via the gap 4, and the tube wall portion 3a of the outer tube 3 between the adjacent spirally wound portions 2a and 2a of the reinforcing core member 2 is gently inward. Since it is curved, at the outer peripheral wall portion of the hose where the tensile force acts, the tube wall portion 3a of the outer tube 3 is tensioned so as to eliminate the concave arc-shaped slack and absorbs the tensile force. At the inner peripheral wall of the hose where the force acts, the outer tube 3 is loosened into the concave arc shape. Wall portion 3a is to absorb compressive forces while loosening toward the outer surface of the inner tube 1 more that.

  Accordingly, the resistance force when the hose is bent is small, and the hose can be smoothly bent to a predetermined degree of curvature without buckling, and the inner peripheral surface is formed to be a smooth surface over the entire length. As a result, smooth drainage is achieved with almost no flow resistance.

  Next, the manufacturing method of the drainage hose A having the above-described configuration will be described with reference to FIG. As is well known, while extruding from 16, the opposite side portion of the succeeding strip member portion 11a is superposed on the one side portion of the preceding strip member portion 11a on the base end portion of the metal forming rotating shaft 15 and integrated. While being welded, the inner tube 1 is formed by winding in a spiral with a constant pitch, and in the course of forming the inner tube 1, a semi-molten hard vinyl chloride resin or the like from the second molding nozzle 17 While extruding the synthetic resin reinforcing core material 12 having an elliptical cross section, the pitch substantially equal to the diameter of the major axis side of the reinforcing core material 12 on the synthetic resin band material 11 previously wound on the molding rotating shaft 15 By winding it spirally, its inner circumference The welding together on the synthetic resin strip material 11a.

Further, following the spiral winding of the reinforcing core material 12 on the synthetic resin reinforcing core material 11 wound around the molding rotating shaft 15, from the third molding nozzle 18 from the same synthetic resin as the synthetic resin belt material 11 The soft synthetic resin strip 13 is extruded in a semi-molten state, which is thinner than the synthetic resin strip 11, and the soft synthetic resin strip 13 is spirally wound. A portion facing the outer peripheral surface of the reinforcing core member 12 is formed on the outer peripheral surface of the reinforcing core member 12 so as to be bridged between the outer peripheral surfaces of the spiral wound portions 2a, 2a adjacent to each other in the length direction. Winding in a spiral with a constant pitch while welding and integrating, and overlapping one side of the preceding strip-shaped material portion 13a with the opposite side portion of the following strip-shaped material portion 13a being welded together Thus, the outer tube 3 is formed.

  At this time, since the reinforcing core material 12 is formed in an elliptical cross section, when the synthetic resin belt-like material 13 in a semi-molten state is superposed on the reinforcing core material 12, it is made of a synthetic resin that forms the inner tube 1. The tube of the synthetic resin strip 13 between the adjacent spirally wound portions 2a, 2a of the reinforcing core 12 by the outer peripheral surface of the reinforcing core 12 inclined in a gentle arc shape toward the reinforcing core 11 The wall portion 3a is wound while being bent in a gentle concave arc shape inward, and the inner peripheral surface of the tube wall portion 3a and the outer peripheral surface of the synthetic resin reinforcing core member 11 forming the inner tube 1 A space 4 that is spirally continuous is formed therebetween.

  Thus, while continuously forming the synthetic resin drainage hose on the molding rotary shaft 15, the drainage hose is moved toward the tip of the molding rotary shaft 15 and sent out from the molding rotary shaft 15 in the extending direction thereof. Alternatively, a drainage hose having a predetermined length is obtained by cutting every predetermined length. When the thick end 6 serving as the connection port is formed at the cut portion, a predetermined length is formed on the molding rotary shaft 15. After the drainage hose having a length is formed, although not shown, the thickness of the semi-molten synthetic resin strip 11 which is continuously extruded from the first molding nozzle 16 forming the inner pipe 1 of the drainage hose is increased. On the other hand, the inner tube portion corresponding to twice the length of the connection port is formed by spirally winding on the molding rotating shaft 15.

  Further, the semi-molten synthetic resin reinforcing core member 12 extruded from the second molding nozzle 17 has a small diameter, and the small diameter reinforcing core member is spirally formed so that the inner peripheral portion is buried on the inner tube portion. After being wound and integrally welded, the above-mentioned semi-molten synthetic resin strip 13 extruded continuously from the third molding nozzle 18 is spirally wound around the above-mentioned thick inner tube portion. By continuously welding the outer peripheral surface of the small-diameter reinforcing core from the outer peripheral surface of the tube portion with no gaps, the thick short tube portion is continuously followed by the drainage hose of a predetermined length. A drainage hose having a predetermined length having thick end portions 6 and 6 serving as the connection ports at both ends can be produced by cutting the central portion in the length direction of the thick short tube portion. it can.

The longitudinal side view which abbreviate | omitted one part. The side view. The partially omitted vertical side view when bent. The enlarged vertical side view of the part. The simplified side view which shows a manufacturing method. The partially omitted vertical side view showing a conventional example.

Explanation of symbols

1 Soft synthetic resin inner pipe 2 Reinforcement core material 3 Soft synthetic resin outer pipe
3a Tube wall part 4 Cavity part

Claims (2)

A synthetic resin reinforcing core material is spirally wound around the outer peripheral surface of a soft synthetic resin inner tube having an inner peripheral surface that is a smooth surface over its entire length, and the reinforcing core material is fixed together. A drainage hose in which a soft synthetic resin outer tube is integrally formed on the soft synthetic resin inner tube, and the synthetic resin reinforcing core member has a predetermined pitch on the soft synthetic resin inner tube. On the other hand, the outer tube made of the soft synthetic resin is spirally wound, while the soft synthetic resin outer tube having a certain width is opposed to the following belt-like member portion on one side portion of the preceding belt-like member portion. The inner peripheral surface portion that is spirally wound while overlapping the side portions to be touched and is in contact with the outer peripheral surface of the reinforcing core member is integrally fixed to the outer peripheral surface of the reinforcing core member. The tube wall portion of the outer tube above each spiral winding adjacent in the longitudinal direction Drain hose, characterized in that the surface formed in a curved portion which is curved inwardly so as to lie a gap portion with respect to the outer circumferential surface without close contact with the outer peripheral surface of the inner tube. A semi-molten soft synthetic resin strip is wound spirally on the rotating shaft while the opposite sides of the following strip are overlapped and welded together on one side of the preceding strip. As a result, the inner tube is formed, and a synthetic resin reinforcing core is spirally wound on the outer peripheral surface of the inner tube at a predetermined pitch, and is integrally welded to the outer peripheral surface of the inner tube. by superimposing opposite sides of the strip material portion Rutotomoni reinforcing core member is welded together via the reinforcing core on the tube subsequent to the one side of the strip material portion preceding the soft synthetic resin strip ' while the outer peripheral surface opposed to part of is integrally welded to the outer peripheral surface of the reinforcing core material and the strip material portion on between spiral winding part adjacent to the longitudinal direction of the hose in the reinforcing core, of which The curved surface separated from the outer peripheral surface without the peripheral surface being in close contact with the outer peripheral surface of the inner tube Method for producing a drainage hose and forming an outer tube by winding spirally with form.

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