Hose structure and method of manufacturing the same

A hose 10 of the invention includes an outer hose member 12 composed of a rubber and an inner hose member 14 composed of a resin. A pair of projection ring elements 26 formed on opposite ends of the inner hose member 14 are received in a pair of inner circumferential grooves 24 formed in thick-walled tube elements 18 of the outer hose member 12. The projection ring elements extend the inner circumferential grooves 24 with such dilatation and deformation of the concavity of the inner circumferential grooves 24 enabling the thick-walled tube elements 18 to generate forces acting along the concavity of the inner circumferential grooves 24. Such forces are applied as pressing forces against the projection ring elements 26. The thick wall of the thick-walled tube elements 18 enables the pressing forces to be maintained while the projection ring elements 26 are retained in the inner circumferential grooves 24.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a hose, connected to an external member, 
that provides a fluid flow path and defines an inner-hose flow path 
connecting with the flow path of the external member, and also to a method 
of manufacturing such a hose. More specifically, the present invention 
relates to a novel approach for interconnecting an outer hose member, 
composed of a rubber, with an inner hose member composed of a resin, as 
well as to a method of manufacturing the hose. 
2. Description of the Prior Art 
Recently, use of hose members having high gasoline vapor barrier properties 
have recently gone into fuel flow path applications, for example, in a 
vehicle. FIG. 10 shows a conventional fuel hose structure. An inner hose 
member 200 is substantially concentrically arranged inside an outer hose 
member 100 composed of a resin. An external member, such as a pipe 300, is 
connected to an end of the hose structure with that connection being 
implemented by interposing a separate sealing member 400 between an end 
portion 201 of the inner hose member 200 and the external member 300. The 
outer hose member 100 is then clamped about the inner hose member 200 and 
the sealing member 400 using a clamping ring element 402. Alternatively, 
the end portion of the outer hose member 100 may be extended along its 
axis so that a portion can be turned to lie inside the end portion 201 of 
the inner hose member 200. In this case, the turned end portion of the 
outer hose member 100 works in place of the separate sealing member 400. 
The conventional hose, however, has several problems as discussed below. 
First, however, the conventional hose structure is connected to the 
external member 300 by interposing the separate sealing member 400 between 
the inner hose member 200 and the external member 300, or turning part of 
an extended end portion of the outer hose member 100 inside the inner hose 
member 200, the process of assembly becomes rather complicated and 
time-consuming. Next, the outer hose member 100 can be secured directly to 
the external member 300. In such a case, the end portion 201 of the inner 
hose member 200 does not reach the end portion of the external member 300. 
Further, such a structure results in relatively loose fit between the 
inner hose member 200 and the outer hose member 100. Consequently, there 
are insufficient sealing properties between the outer hose member 100 and 
the inner hose member 200, and this condition is, thereby, impractical. 
SUMMARY OF THE INVENTION 
The object of the present invention is thus to provide an improved hose 
structure that enables an inner hose member to be securely fixed to an 
outer hose member yet maintain the high sealing properties between the 
outer hose member and the inner hose member. Another objective is to 
simplify the procedure for fixing the hose structure to an external 
member. 
At least part of the above and the other related objectives is realized by 
a hose that connects with an external member, thus providing a flow path 
of a fluid, and defines an inner-hose flow path that connects with the 
flow path of the external member. The hose of the invention includes: an 
outer hose member composed of a rubber material and comprising a first 
tube element formed on an end thereof, with an external member being fit 
into and connected to the first tube element. The inner hose member is 
composed of a resin and arranged inside the outer hose member to define 
the inner-hose flow path. The outer hose member includes a second tube 
element extending from the first tube element and having a wall thickness 
that will apply and maintain a restoring force when the second tube 
element is dilated in a diametric direction along the length of the hose. 
The second tube element has an inner circumferential groove formed as an 
annular concavity about an inner circumferential face thereof. The inner 
hose member also includes a projection ring element formed as a circular 
convexity that will be fitted into and extend the inner circumferential 
groove. 
In the hose of the present invention when constructed and assembled, the 
inner hose projection ring element is fitted into the inner 
circumferential groove of the second tube element of the outer hose member 
thereby extending the inner circumferential groove. This structure defines 
the arrangement of the inner hose member relative to the outer hose member 
and securely fixes the inner hose member to the outer hose member. The 
completed hose, accordingly, has a double-layer structure including the 
resin inner hose member arranged inside the rubber outer hose member. The 
external member is fitted into and connected to the first tube element of 
the outer hose member, so that the inner-hose flow path, defined by the 
inner hose member, connects with the fluid flow path of the external 
member. 
The concave area of the inner circumferential groove formed in the outer 
hose member is dilated and deformed by the projection ring element of the 
inner hose member. Such dilatation and deformation of the rubber material 
of the outer hose member causes the second tube element of the outer hose 
member to produce a restoring force. The restoring force is applied as a 
pressing force onto the projection ring element of the inner hose member. 
The thick-walled second tube element enables such a pressing force to be 
maintained while the projection ring element is fitted in the inner 
circumferential groove. The pressing force also enables the inner hose 
member to be securely fixed to the outer hose member with high sealing 
properties through the fitting of the projection ring element into the 
inner circumferential groove. The hose structure of the present invention 
allows the external member to be directly fitted into and attached to the 
first tube element of the outer hose member. Unlike the conventional 
structure, the hose structure of the present invention does not require 
interposition of any additional or separate element nor does it require 
any portion of the end of the outer hose member to be turned back upon 
itself or be folded over. The hose structure of the present invention thus 
favorably simplifies the procedure of suitably clamping, sealing, and 
fixing the hose to the external member. 
The hose of the present invention may have structures according to the 
following embodiments. 
In accordance with a first embodiment, the projection ring element has a 
diametric dimension that is 10 to 20% greater than that of the inner 
circumferential groove of the second tube element in a non-dilated state 
and a longitudinal dimension, along the length of the hose, that is 0.5 to 
2 mm longer than that of the inner circumferential groove. 
Through the simple adjustment of the dimensions, the structure of the first 
embodiment enables the projection ring element of the inner hose member to 
be fitted into the inner circumferential groove of the outer hose member 
while dilating and deforming the concavity of the inner circumferential 
groove. 
In accordance with a second embodiment, the projection ring element is 
composed of a complex material that is obtained by mixing a reinforcing 
material with the resin. 
The structure of the second embodiment has an advantage in that when the 
projection ring element of the inner hose member is fitted into the inner 
circumferential groove of the outer hose member, to extend the inner 
circumferential groove, the inner hose projection ring element receives a 
pressing force applied by the second tube element of the outer hose 
member. In the structure of the second embodiment, the inner hose 
projection ring element is composed of a complex material having 
reinforcing fibers, or the like, contained in the resin, and, accordingly, 
has the required strength to resist the pressing force. Such resistance 
can be further enhanced by increasing the wall thickness of the inner hose 
projection ring element in a diametric direction. 
In accordance with a third embodiment, the materials of the outer hose 
member and the inner hose member are appropriately selected. The outer 
hose member is composed of a rubber material having high fire resistance, 
abrasive resistance, and oil resistance. Available examples include 
butadiene rubbers, such as butadiene-acrylonitrile copolymer (NBR), a 
rubber mixture of butadiene-acrylonitrile copolymer (NBR) and polyvinyl 
chloride (PVC), ether rubbers, such as epichlorohydrin rubber (CO) and 
epichlorohydrin-ethylene oxide copolymer (ECO), and fluororubbers, such as 
vinylidene fluoride-hexafluoropropylene-tetrafluoroethylene terpolymer 
(FKM). 
In the third embodiment, no specific material but a conventional, known 
material is adopted for the outer hose member. 
In accordance with a fourth embodiment, the inner hose member is composed 
of either a polyamide resin or a fluororesin, which has excellent barrier 
properties against gasoline fuel and is, accordingly, suitable for a fuel 
hose, for example, in a vehicle. 
In accordance with a fifth embodiment, the inner hose member has a 
double-layer structure including an inner layer composed of a fluororesin 
and an outer layer composed of a polyamide resin. 
In the fifth embodiment, the inner layer has excellent barrier properties 
against alcohols, whereas the outer layer has the high resistance against 
pressing or constricting forces. This structure improves the durability 
the hose structure used as a fuel hose. 
In accordance with a sixth embodiment, the outer hose member further 
includes a first bellows tube element, and the inner hose member has a 
second bellows tube element that is in contact with an inner-most 
diametric portion of the first bellows tube element. 
In the sixth embodiment, the outer hose member and the inner hose member 
are in contact with each other only at the respective rises of the first 
bellows tube element and the second bellows tube element. This structure 
lowers the frictional resistance and enables the hose to be curved or bent 
without any difficulties. This leads to improved hose flexibility as well 
as in workability, for example, when bending the hose. 
In accordance with a seventh embodiment, the outer hose member includes a 
pair of the first tube elements formed on both ends thereof and a pair of 
the second tube elements that have an identical shape and respectively 
extend from the first tube elements. The inner hose member includes a pair 
of the projection ring elements, that have an identical shape, and are 
arranged at a pitch corresponding to the pitch of a pair of the inner 
circumferential grooves formed in the pair of the second tube elements. 
In the seventh embodiment, when the inner hose member is inserted into the 
outer hose member from either end, the protection ring elements can be 
fitted into the respective inner circumferential grooves. This structure 
does not specify the direction of insertion of the inner hose member into 
the outer hose member, and the procedure of assembly is, thus, favorably 
simplified. 
The present invention is also directed to a method of manufacturing a hose 
with an outer hose member composed of a rubber and an inner hose member 
composed of a resin and arranged inside the outer hose member. The hose 
connects with an external member, that provides a flow path for a fluid, 
and has an inner-hose flow path defined by the inner hose member to 
connect with the flow path of the external member. 
The method includes the steps of: 
(a) forming a first tube element on one or opposite ends of the outer tube 
to securely hold and connect with the external member, and forming a 
second tube element extending away from the first tube element and having 
a wall thickness sufficient to apply and maintain a restoring force or 
forces, when the second tube element is dilated, in a diametric direction 
about the inner hose, the second tube element comprising an inner 
circumferential groove formed as a circular concavity in an inner 
circumferential face thereof; 
(b) providing the inner hose member with a projection ring element that is 
formed as a circular convex and arranged to be fitted or placed into the 
inner circumferential groove so as to extend about the inner 
circumferential groove; 
(c) expanding the outer hose member in a diametric direction, along the 
length thereof and then placing the inner hose member inside the outer 
hose member at a predetermined position to arrange the projection ring 
element opposite to the inner circumferential groove; and 
(d) canceling or releasing the expansion of the outer hose member. 
In the method of the present invention, the resin inner hose member is 
placed inside the rubber outer hose member, while the outer hose member is 
diametrically expanded along the length thereof. This enables the inner 
hose member to be readily inserted into the outer hose member and arranges 
the inner hose projection ring element at a specific position to face the 
inner circumferential groove of the outer hose member. After the 
projection ring element is fitted into the expanded inner circumferential 
groove, the expansion of the outer hose member is canceled to restore the 
inner circumferential groove to its original shape. The cancellation of 
the expansion also enables the inner hose projection ring element to be 
fitted in and extend the inner circumferential groove of the outer hose 
member. The hose that includes the inner hose member securely fixed to the 
outer hose member with high sealing properties and is clamped and fixed to 
the external member by a simple procedure is readily manufactured by the 
method of the present invention. 
However, a variety of techniques may be adopted to diametrically expand the 
outer hose member along its length. By way of example, a cap body, having 
a blow hole for compressed air, is hermetically attached to one end of the 
outer hose member while the discharge of the air from the other end is 
restricted. The difference between the air blown out of the cap and the 
discharged air causes the outer hose member to expand diametrically along 
its length. The discharge of the air can be restricted by closing the 
opening of the outer hose member at the other end by the inner hose member 
having the air-tight inner-hose flow path. 
The method of the present invention may go into a variety of applications, 
some of which are discussed below. 
In accordance with a first application, the step (a) includes the step of 
providing the outer hose member molded into a curved shape, and the step 
(b) includes the step of providing the inner hose member that is also 
molded into a curved shape corresponding to the curved shape of the outer 
hose member. The step (c) can include the steps of expanding the outer 
hose member in a diametric direction, along the length thereof, while 
stretching the curved outer hose member and keeping the outer hose member 
straight. The inner hose member can then be arranged inside the outer hose 
member while stretching the curved inner hose member and keeping the inner 
hose member straight. 
The first application enables the hose of a curved shape to be readily 
manufactured by providing the curved outer hose member and the curved 
inner hose member and carrying out expansion of the outer hose member, 
insertion of the inner hose member into the outer hose member, and 
cancellation of the expansion while the outer hose member and the inner 
hose member are kept straight. 
In accordance with a second application, the method further includes the 
step of thermally treating the hose comprising the inner hose member 
arranged inside the outer hose member, so as to thermally deform the hose 
to have a curved hose conduit. 
The second application has the post treatment step of thermally treating 
and deforming the hose of a straight shape after cancellation of the 
expansion of the outer hose member. This application also enables the hose 
of a curved shape to be readily manufactured. 
These and other objects, features, aspects, and advantages of the present 
invention will become more apparent from the following detailed 
description of the preferred embodiments with the accompanying drawings in 
which like reference numerals are used for the same parts in various views 
.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Some modes of carrying out the present invention are described as preferred 
embodiments. 
Referring to the first embodiment in FIG. 1, the hose 10 includes an outer 
hose member 12 to which external members 11 are connected. An inner hose 
member 14 is arranged inside the outer hose member 12 to be substantially 
concentric with the outer hose member 12 along the length thereof. The 
outer hose member 12 is made of a rubber, and includes fitting tube 
elements 16 formed on both ends thereof, second tube elements 18 that 
extend axially away from the fitting tube elements 16 and have thicker 
walls in the diametral direction. Outer hose 12 also includes a bellows 
portion 20 and a straight tube portion 22 formed between the thick-walled 
tube elements 18 as shown in FIG. 1. 
Where hose 10 is used for gasoline or fuel flow, the bellows portion 20 has 
an outer diameter of approximately 40 to 80 mm at the rise of the bellows 
and an inner diameter of approximately 30 to 70 mm at the fall of the 
bellows. The pitch of the rise and fall of the bellows portion 20 is 
approximately 10 to 20 mm. The inner diameter of the straight tube element 
22 is approximately 30 to 70 mm, which is similar to the inner diameter at 
the bottom of the bellows portion 20. Both the bellows portion 20 and the 
straight portion 22 have a wall thickness of approximately 3 to 5 mm. 
The fitting tube elements 16 have a wall thickness of approximately 4 to 5 
mm in order to apply a sufficient clamping force against and to securely 
seal about the external members 11. The inner diameter of the fitting tube 
element 16 is naturally a little smaller than the outer diameter of the 
external member 11. The thick-walled second tube element 18 rises 
outwardly from the fitting tube element 16. An inner circumferential 
groove 24 is formed as a ring-shaped concavity in an inner circumferential 
face of each thick-walled tube element 18. 
Referring to FIG. 2, the thick-walled tube element 18, with the inner 
circumferential groove 24, is deflected inwardly in the direction of its 
diameter, before a fitting projection ring element 26 is fitted into the 
inner circumferential groove 24, which is discussed later. An end portion 
of the fitting tube element 16, close to the inner circumferential groove 
24, follows the deflection of the thick-walled tube element 18 and sags 
inwardly. Such inward positions are shown by comparing the full and 
dot-dash lines in FIG. 2. The thick-walled tube element 18 has a 
predetermined wall thickness in order to apply and maintain a restoring 
force in a diametral direction along the length of the hose 10 when the 
concavity of the inner circumferential groove 24 is deformed and dilated 
as shown by the two-dot chain line in the drawing of FIG. 2. For example, 
the thick-walled tube element 18 has a wall thickness of approximately 4 
to 6 mm, which is substantially equal to the wall thickness of the fitting 
tube element 16 in this embodiment. 
When each external member 11 is fitted into one end of the hose 10, the 
inner wall of the fitting tube element 16, on the side closest to the 
inner circumferential groove 24, is deformed diametrically outwardly by a 
curved projection element 11a formed on an end portion of the external 
member 11. This further improves the sealing properties of the end portion 
of the external member 11. 
The inner circumferential groove 24 has a concave shape complimenting the 
outline of the fitting projection ring element 26 of the inner hose member 
14. In order to press and clamp the inner hose projection ring element 26 
securely in the direction of the diameter of hose 10, the inner 
circumferential groove 24 has an inner diameter A, which is originally set 
to be a little smaller than the outer diameter of the projection ring 
element 26 while being free from the insertion of the projection ring 
element 26. By way of example, when the outer diameter of the fitting 
projection ring element 26 is equal to 42 mm, the inner diameter A of the 
inner circumferential groove 24 should be set to approximately 37 mm. An 
effective groove width B (that is, distance between corners of the groove) 
of the inner circumferential groove 24 can be determined appropriately, 
but is preferably set to be about 5 through about 10 mm. The effective 
groove width B within this range enables the inner circumferential groove 
24 to press and clamp the exterior of inner hose projection ring element 
26 when fitted into the inner circumferential groove 24, as discussed 
later. 
Since hose 10 of this embodiment is used to establish a gasoline or fuel 
flow path, the outer hose member 12 should be composed of a material 
having high flame resistance, wear and abrasion resistance, as well as oil 
resistance. The material adopted in this embodiment is a rubber mixture of 
butadiene-acrylonitrile copolymer (NBR) and polyvinyl chloride (PVC). The 
outer hose member 12, having the shape and the dimensions specified above, 
is prepared by vulcanizing the rubber mixture at a temperature ranging 
from 170.degree. C. to 190.degree. (C. and molding the vulcanized rubber 
mixture. 
The inner hose member 14, arranged inside the outer hose member 12, is 
composed of a resin. As shown in FIG. 1, the inner hose member 14 is 
placed at a specific position within the outer hose member 12 to define an 
inner-hose flow path 15 that connects with flow paths 13 defined by the 
external members 11. Namely, while the inner hose member 14 is positioned 
in the outer hose member 12, the external members 11 come into contact 
with the inner hose member 14 to connect the flow paths 13 to the 
inner-hose flow path 15. 
As shown in FIG. 1 and the enlarged sectional view of FIG. 3, the inner 
hose member 14 has a pair of fitting projection ring elements 26 that 
project from both ends thereof, a pair of intermediate elements 28 
extending away from the fitting projection ring elements 26 and having a 
gradually decreasing wall thickness, and a bellows portion 30 formed 
between the pair of intermediate elements 28. 
The outer diameter of the bellows portion 30 of the inner hose member 14 at 
the rise is set substantially equal to the inner diameter of the bellows 
portion 20 of the outer hose member 12, while the fall of the bellows 
portion 30 is substantially equal to the inner diameter of the straight 
tube element 22 of the outer hose member 12, so that the inner hose member 
14 can be easily disposed inside the outer hose member 12. The pitch of 
the rise and fall of the bellows portion 30 of the inner hose member 14 is 
a little narrower than the same of the bellows portion 20 of the outer 
hose member 12, and set to be approximately 1 to 5 mm. The bellows portion 
30 has a wall thickness of approximately 0.2 to 1.0 mm. 
Each projection ring element 26 has a large wall thickness, in the 
direction of its diameter to possess a sufficient resistance against 
pressing forces applied by the thick-walled tube element 18. When the 
projection ring element 26 is mounted into the concavity of the inner 
circumferential groove 24 of the thick-walled tube element 18 the larger 
size of the projection ring element 26 dilates and deforms the concavity. 
In this embodiment, the projection ring elements 26 have a wall thickness 
of approximately 2.5 mm in the diametral direction. By taking into account 
the material of the inner hose member 14, the thickness of the projection 
ring elements 26 is appropriately designed to have a sufficient resistance 
against the pressing force. The forces being applied against projection 
ring elements 26 are shown by the arrows in FIG. 6. As this FIG. 6 
demonstrates, the holding, sealing and restraining forces, are directed 
radially inwardly about the upper surface of projection ring elements 26. 
Some forces extend radially inwardly directly while others are at various 
angles depending upon the surface interaction between groove 24 and ring 
elements 26. 
The projection ring element 26 has an outer surface with a convex shape 
corresponding to the concave shape of the inner circumferential groove 24. 
The projection ring element 26 has an outer diameter A', which is 
approximately 5 mm larger than the inner diameter A (for example, 37 mm) 
of the inner circumferential groove 24. An effective width B' (that is, 
distance between corners of the convex) of the projection ring element 26 
is approximately 0.5 mm longer than the effective groove width B of the 
inner circumferential groove 24. The outer diameter A' and the effective 
width B' of the projection ring element 26 are determined corresponding to 
the size of the inner circumferential groove 24. Where the inner diameter 
A and the effective groove width B of the inner circumferential groove 24 
are changed, with a variation in inner diameter of the straight tube 
element 22, the outer diameter A' and the effective width B' of the 
fitting projection ring element 26 are also varied to correspond to any 
such change. In addition, as shown in FIG. 6, the outer end wall 32, shown 
in FIG. 3, has a portion 34 that extends radially beyond the corresponding 
wall 36 of outer tube 16. Thus, as in FIG. 1, when external member 11, 
such as a pipe, is inserted into fitting tube element 16, the radially 
extending portion 34 of wall 32 extends over the end wall of external 
member 11 and provides a smooth transition between the interior surface of 
inner tube 14 and the interior surface of external member 1. 
Since hose 10 of the first embodiment is used for gasoline or fuel lines, 
the inner hose member 14 is preferably composed of nylon 11, that is one 
of polyamide resins, and has sufficient flexibility and barrier properties 
against gasoline fuel. The inner hose member 14 having the shape and 
dimensions specified above is prepared, for example, by extrusion blow 
molding. Fluidized nylon 11 is extruded from an extruder die to form a 
parison and the parison is then blow molded in a molding die. The 
projection ring element 26 is formed to have the greater wall thickness by 
controlling the parison in the process of extrusion from the extruder die, 
and is blow molded to the convex shape with the above-specified dimensions 
in the blow molding die. 
In accordance with another preferable application, the inner hose member 14 
may be prepared by multi-layer blow molding; a fluororesin is used as an 
inner layer 27 and another resin as an outer layer. A preferable example 
of another resin is polyamide resin. In this configuration, the inner 
layer of fluororesin 27 improves the barrier properties against alcohols, 
whereas the outer layer of polyamide resin assures a sufficient resistance 
against the desired pressing forces. 
The following describes a process of manufacturing the hose 10 thus 
constructed. Referring to FIG. 4, one of the fitting tube elements 16 of 
the outer hose member 12 is placed into an air blow jig 40. With the outer 
hose member 12 attached to the air blow jig 40, and the fitting tube 
element 16 being hermetically sealed to the air blow jig 40 by an O-ring 
41 one end is ready. A dilatation jig 42 is, on the other hand, inserted 
into the opposite fitting tube element 16 to dilate that opposite end as 
shown by the arrows in the direction of its diameter. Compressed air, 
supplied from a compressed air source 43, such as a compressor, is blown 
into the outer hose member 12 via a valve 44 and an air blow hole 45 in 
jig 40. Compressed air is continuously blown in until valve 44 is closed. 
In parallel to the dilatation of the opposite fitting tube element 16 by 
dilatation jig 42 and the blowing of compressed air through the air blow 
jig 40, a specific procedure is then carried out to arrange the inner hose 
member 14 inside the outer hose member 12. 
Referring to FIG. 5, a hose support shaft 46 is set in the inner-hose flow 
path 15, defined by the inner hose member 14, in order to support the 
inner hose member 14. Then, the inner-hose flow path 15 is hermetically 
sealed, relative to the outside, by air bladders 48 formed around each of 
a pair of flanges 47 that are spaced apart along the hose support shaft 
46. Air is forced through an air conduit 46a, formed in the hose support 
shaft 46, to distend the air bladders 48, so as to support the inner hose 
member 14 and maintain the air tightness of the inner-hose flow path 15. 
The inner hose member 14, supported in the above manner, is thereafter 
shifted to the opening of the fitting tube element 16 of the outer hose 
member 12 that has already been dilated by the dilatation jig 42, and is 
subsequently inserted through the dilated fitting tube element 16 into the 
outer hose member 12. Insertion of the inner hose member 14 having the 
air-tight inner-hose flow path 15 enables the opening of the fitting tube 
element 16 to be closed by one end portion of the inner hose member 14. 
The inner hose member 14 thereby interferes with the air blowing through 
the inner hose 12 and out of the dilated opening of the fitting tube 
element 16. The pressure of the compressed air supplied by the air blow 
jig 40 diametrically expands the outer hose member 12 along its length 
from its original shape shown by the two-dot chain line in FIG. 4. While 
the outer hose member 12 is being expanded, the inner hose member 14, 
supported by the hose support shaft 46, is inserted into the outer hose 
member 12 until the projection ring elements 26 of the inner hose member 
14 are positioned to face and are positioned into a corresponding inner 
circumferential groove 24 at opposite ends of the outer hose member 12. 
After the inner hose member 14 is positioned inside the outer hose member 
12, valve 44 is shut to stop the flow of compressed air. Also, dilatation 
jig 42 returns to an undilated position and is taken out of that fitting 
tube element 16. This cancels the expansion of the outer hose member 12 
and the dilatation of the fitting tube element 16. After the projection 
ring elements 26 are received by their corresponding inner circumferential 
grooves 24, respectively, the expanded inner circumferential grooves 24 
are likewise restored to their original shape. This enables each of the 
projection ring elements 26 of the inner hose member 14 to be securely 
retained in the concavity of the inner circumferential grooves 24 of the 
outer hose member 12 while also, due to the size differences, still 
dilating and deforming that concavity. In accordance with another possible 
application, a jig (not shown) may be used to draw the outer hose member 
12 against projection rings 26 after the flow of compressed air has 
stopped in order to assure the proper relationship between the projection 
ring elements 26 and the inner circumferential grooves 24. 
The outer hose member 12 with the inner hose member 14 arranged therein is 
then separated from the air blow jig 40, so that the completed hose 10 has 
the inner hose member 14 substantially concentrically arranged inside the 
outer hose member 12 along its length (see FIG. 1). The completed hose 10, 
accordingly, has a double-layer structure. That is, the resin inner hose 
member 14 is arranged inside the rubber outer hose member 12. The external 
members 11 are then inserted into the fitting tube elements 16, formed on 
either ends of the outer hose member 12 of the hose 10, and fixed by 
clamps (not shown). Hose 10 is thus connected to the external members 11 
so that the flow paths 13, defined by the external members 11, connect 
with the inner-hose flow path 15 defined by the inner hose member 14. 
Fuel, such as gasoline, will smoothly flow through hose 10 relative to the 
external members 11. Simultaneously with, or otherwise immediately before 
or after, the separation of the outer hose member 12 from the air blow jig 
40, the hose support shaft 46 is pulled out of the inner hose member 14. 
Stopping the flow of air to air bladders 48 also return them to their 
contracted state. This allows shaft 46 to be withdrawn from within inner 
hose 14. 
In hose 10 according to the first embodiment discussed above, the 
projection ring elements 26 are retained in the inner circumferential 
grooves 24 formed in the thick-walled tube elements 18 of the outer hose 
member 12 with the inner circumferential grooves 24 in an extended state. 
Placement of projection ring elements 26 into the inner circumferential 
grooves 24 also defines the arrangement of the inner hose member 14 with 
respect to the outer hose member 12 and fixes the inner hose member 14 
within the outer hose member 12. 
By having the projection ring elements 26 of the inner hose member 14 
extend the inner circumferential grooves 24 of the outer hose member 12, 
that deformation of the rubber material causes the thick-walled tube 
elements 18 to produce forces that are applied along the concavity of the 
inner circumferential grooves 24 as shown by the arrows in the drawing of 
FIG. 6. Such forces act as a pressing force against the projection ring 
elements 26 to both hold and tightly seal about the projection rings 22. 
The thick wall of the thick-walled tube elements 18 enables such pressing 
forces to be maintained while the projection ring elements 26 are retained 
within the inner circumferential grooves 24 formed in those thick-walled 
tube elements 18. In hose 10 according to the first embodiment, such 
pressing forces enable the inner hose member 14 to be securely fixed to 
the outer hose member 12 with high sealing properties through the 
projection ring elements 26 within the inner circumferential grooves 24. 
The structure of the embodiment also allows each external member 11 to be 
directly attached to the fitting tube element 16 of the outer hose member 
12. Unlike the conventional hose structure, the hose structure 10 of the 
embodiment does not require interposition of any additional or separate 
element or turn-up of the end portion of the outer hose member. The hose 
structure 10 of this first embodiment thus favorably simplifies the 
process of clamping and fixing the hose 10 to the external members 11. 
The method discussed previously to manufacture hose 10 according to the 
first embodiment expands the outer hose member 12, in the direction of its 
diameter along its length, before the inner hose member 14 is placed 
inside the outer hose member 12. This enables the inner hose member 14 to 
be readily inserted into the outer hose member 12. The subsequent 
cancellation of the expansion of the outer hose member 12 enables the 
projection ring elements 26 of the inner hose member 14 to be securely 
received in the concavity of the inner circumferential grooves 24 while 
projection ring elements 26 continue to dilate and deform the concavity. 
Consequently, hose 10 by a simple procedure is constructed from an inner 
hose member 14 that is securely fixed to an outer hose member 12 with high 
sealing properties therebetween, with the resulting hose being easily 
clamped and fixed to external members 11. 
The hose 10 of the first embodiment has the following advantages other than 
those specified above. 
(1) Hose 10 includes a bellows portion 20 of the outer hose member 12 and a 
bellows portion 30 of an inner hose member 14, which overlap each other 
along the length of the bellows portion 20. This structure enables hose 10 
to be curved gently or otherwise expanded or contracted, to some extent, 
along the length of the bellows portion 20. This increases the degree of 
freedom of the hose in connecting together the two external members 11 and 
extends the applicable range of the hose 10. The outer bellows portion 20 
and the inner bellows portion 30 effectively absorb the expansion and 
contraction of the hose 10 occurring in use. 
(2) In the hose 10, only the rises of the bellows portion 30 of the inner 
hose member 14 come into contact with the outer hose member 12. This 
structure lowers the frictional resistance and enables the inner hose 
member 14 to be independently curved or otherwise expanded or contracted 
without any difficulties. This leads to improved flexibility of the hose 
10 as well as in workability, for example, bending of the hose 10. 
(3) The hose 10 includes an air space defined between the outer bellows 
portion 20 and the inner bellows portion 30. This air space provides a 
heat shielding effect which enhances the heat resistance and fire 
resistance of the hose against gasoline or fuel flowing through the 
inner-hose flow path 15. 
(4) The hose 10 has the double-layer structure including the outer hose 
member 12 and the inner hose member 14. The outer hose member 12 is 
composed of a rubber having the high fire resistance, for example, a 
rubber mixture of butadiene-acrylonitrile copolymer (NBR) and polyvinyl 
chloride (PVC), whereas the inner hose member 14 is made of a polyamide 
resin, for example, (nylon 11) having high barrier properties. These 
materials, in combination with the heat shielding effect of the air space, 
further enhance the heat resistance and fire resistance against gasoline 
or other fuel. The barrier properties of the inner hose member 14 also 
effectively prevent gasoline or other fuel and vapors from leaking out of 
the inner-hose flow path 15. 
(5) In the hose 10 of the first embodiment, the inner hose member 14 can 
have the bellows portion 30 formed along the whole length of the inner 
hose member 14 except at the projection ring elements 26 and the 
intermediate elements 28. When the inner hose member 14 is inserted into 
the outer hose member 12 from either end, the bellows portion 30 of the 
inner hose member 14 and the bellows portion 20 of the outer hose member 
12 concentrically overlap. The inner circumferential grooves 24 formed on 
both ends of the outer hose member 12, as well as the projection ring 
elements 26 formed on both ends of the inner hose member 14, have 
substantially the identical shape and dimensions. When the inner hose 
member 14 is inserted into the outer hose member 12 from either end, the 
projection ring elements 26 can be received by the inner circumferential 
grooves 24. This structure does not specify the direction of insertion of 
the inner hose member 14 into the outer hose member 12, and the procedure 
of assembly is thus favorably simplified. 
Another hose 10A described below as a second embodiment according to the 
present invention has a significantly curved hose conduit. In the hose 10A 
of the second embodiment, like elements that have the same functions as 
those in the first embodiment are shown by like numerals with the symbol 
`A` and are not further described here. 
Referring first to FIG. 7, hose 10A of the second embodiment also has a 
double-layer structure; an inner hose member 14A that is substantially 
concentrically arranged inside an outer hose member 12A along its length. 
The outer hose member 12A has a curved portion as shown in FIG. 7. A 
bellows portion 20A of the outer hose member 12A is contracted in a range 
corresponding to inside of the curved portion, while being expanded in a 
range corresponding to outside of the curved portion. In the hose 10A of 
the second embodiment, projection ring elements 26A are fitted and secured 
into the concavity of inner circumferential grooves 24A that continue to 
be formed in thick-walled tube elements 18A which are dilated and expanded 
along the concavity. The pressing force applied by the thick-walled tube 
elements 18A enables the inner hose member 14A to be securely fixed to the 
outer hose member 12A with high sealing properties. Like the first 
embodiment, the outer hose member 12A of the hose 10A can be clamped 
directly to external members. This favorably simplifies the procedure of 
clamping and fixing the hose 10A to the external members. 
The hose 10A of the second embodiment is manufactured in the following 
manner. The outer hose member 12A is prepared by vulcanizing a rubber 
mixture of butadiene-acrylonitrile copolymer (NBR) and polyvinyl chloride 
(PVC), at the temperature of 170.degree. C. to 190.degree. C. and then 
molding the vulcanized rubber mixture. The outer hose member 12A is molded 
to have the curved bellows portion 20A as shown in FIG. 8(a). While the 
curved outer hose member 12A is stretched and kept straight, as in FIG. 
8(b), by some means (not shown), the air blowing jig 40 and the dilatation 
jig 42, mentioned previously in the first embodiment, are attached to 
opposite ends of the outer hose member 12A to blow the compressed air into 
one end of the outer hose member 12A and dilate a fitting tube element 16A 
at the opposite end (see FIG. 4 in the first embodiment). Alternatively, 
the outer hose member 12A may be stretched or straightened after the air 
blow jig is attached to the outer hose member 12A. 
The inner hose member 14A is prepared in the following manner. A straight 
blow-molded object, shown in FIG. 9(a), is obtained by extrusion blow 
molding, that is, by extruding fluidized nylon 11 from an extruder die 
into a parison and then by blowing the parison in a molding die. The 
straight blow-molded object is then placed in a mandrel having an inner 
tube portion curved to a specified shape, it is thermally treated at 
100(C. for five minutes, and subsequently cooled. This procedure gives the 
inner hose member 14A, as shown in FIG. 9(b), a curved shape similar to 
the outer hose member 12A (see FIG. 8(a)). The inner tube portion of the 
mandrel has a diameter corresponding to the required diameter of the inner 
hose member 14A. The curved inner hose member 14A is forcibly stretched, 
and the hose support shaft 46 is then inserted into an inner-hose flow 
path 15A of the inner hose member 14A so as to keep the inner hose member 
14A straight (see FIG. 5). 
The same steps as those in the process of manufacturing the hose 10 of the 
first embodiment are then carried out. These steps include insertion of 
the inner hose member 14A into the outer hose member 12A, cessation of the 
blowing of compressed air, restoration and removal of the dilatation jig 
42, separation of the outer hose from the air blowing jig 40, and removal 
of the hose support shaft 46. After the hose support shaft 46 is taken out 
of the inner hose member 14A and the means for keeping the outer hose 
member 12A straight is removed, the outer hose member 12A and the inner 
hose member 14A are restored to the their original curved shapes, so that 
the curved hose 10A shown in FIG. 7 is completed. 
Like hose 10 of the first embodiment, hose 10A of the second embodiment, 
having the significantly curved hose conduit, can be readily manufactured 
by molding the curved outer hose member 12A and the curved inner hose 
member 14A and by keeping both the hose members 12A and 14A straight 
during the assembly. 
The present invention is not restricted to the above embodiments since but 
there may be many modifications, changes, and alterations without 
departing from the scope or spirit of the main characteristics of the 
present invention. 
By way of example, hose 10A, having the significantly curved hose conduit, 
may be manufactured in the following manner. The hose 10 including the 
straight outer hose member 12 and the straight inner hose member 14 to 
define the straight hose conduit is manufactured first according to the 
process specified in the first embodiment. Heat treatment suitable for the 
material of the hose 10 is then carried out to thermally deform the hose 
10 to the shape of hose 10A having the significantly curved form. This 
procedure enables the hose having the double-layer structure of a 
relatively sharp curvature, such as 60 degrees or 90 degrees, to be 
readily manufactured. The resulting hose has the inner hose member 
securely fixed to the outer hose member and with high sealing properties 
therebetween. 
It should be clearly understood that the above embodiments are only 
illustrative and not restrictive in any sense. The scope and spirit of the 
present invention are limited only by the terms of the appended claims.