Double pipe heat exchanger and method for manufacturing the same
Abstract
A heat exchanger and a method for manufacturing the same provides a double pipe heat exchanger including an outer pipe, an inner pipe forming a first fluid passage and a second fluid passage between the inner pipe and the outer pipe, first and second connecting pipes to pass fluid from the outside and exhaust the fluid by connecting ends of the outer pipe, and a connector to connect the inner pipe and each connecting pipe to the outer pipe. The connector includes expanded ends of the outer pipe and a reducing part configured to assemble the inner pipe inserted in the outer pipe with an end of each connecting pipe by forming at an end of each expanding part with a pressing process. The center line of the inner pipe connected to the connector is disposed at an upper side of the inner circumference surface of the outer pipe.
Claims
exact text as granted — not AI-modified1 . A double pipe heat exchanger comprising:
an outer pipe, an inner pipe configured to form a first fluid passage internally and a second fluid passage between the inner pipe and the outer pipe by inserting into the outer pipe, a first connecting pipe and a second connecting pipe configured to pass a fluid from the outside and exhaust the fluid by connecting to both ends of the outer pipe, and a connector configured to connect the inner pipe and each connecting pipe and to the outer pipe; wherein the connector comprises an expanding part formed by expanding both ends of the outer pipe and a reducing part configured to assemble the inner pipe inserted in the outer pipe with an end of each connecting pipe and by forming at an end of each expanding part with a pressing process; and the center line of the inner pipe connected to the connector is disposed at an upper side of the inner circumference surface of the outer pipe.
2 . The double pipe heat exchanger of claim 1 , wherein each reducing part comprises:
a first reducing part configured with a first coupling hole assembled by inserting into the inner pipe; a second reducing part formed at an end of the first reducing part and configured with a second coupling hole for assembling ends of each connecting pipe and; and a separating part formed between the first reducing part and the second reducing part, and configured to separate the first reducing part and the second reducing part.
3 . The double pipe heat exchanger of claim 2 , further comprising:
a bend formed at both ends of the inner pipe located in expanding parts of each connector in a curved shape along the inner circumference surface of the expanding part so that the inner pipe can be disposed parallel to the outer pipe by inserting the inner pipe into the outer pipe in the lengthwise direction.
4 . The double pipe heat exchanger of claim 3 , wherein each connecting pipe is assembled parallel to an identical line of the outer pipe and disposed parallel to the inner pipe 100 exposed from both ends of the outer pipe.
5 . The double pipe heat exchanger of any of claims 1 , wherein a plurality of spiral parts formed in a spiral shape along the lengthwise direction of the inner circumference surface is further composed in the outer pipe so that the second fluid passage has a spiral shape at least partially.
6 . A method for manufacturing a double pipe heat exchanger having an outer pipe, an inner pipe configured to be formed with a first fluid passage internally and formed with a second fluid passage between the inner pipe and the outer pipe by inserting in the outer pipe, a first connecting pipe and a second connecting pipe passing a fluid from the outside and exhausting the fluid by connecting to both ends of the outer pipe, and a connector configured to connect the inner pipe and each connecting pipe and to the outer pipe, the method comprising the steps of:
(a) preparing the outer pipe and the inner pipe; (b) forming an expanding part of the connector by expanding both ends of the outer pipe: (c) forming a bend at parts of the inner pipe located at each expanding part of the outer pipe; (d) inserting the inner pipe into the outer pipe through the expanding part and inserting each connecting pipe and into each expanding part of the outer pipe at the same time; (e) forming a reducing part of the connector by pressing an end of an outer circumference surface of each expanding part through a pressing process in order to assemble the inner pipe and each connecting pipe and; and (f) finally fixing assembled parts of the inner pipe and each connecting pipe and in the connector through a braising process.
7 . The method of claim 6 , wherein, at the step (c), the bend is formed in a curved shape along the inner circumference surface of the expanding part so that a part of the inner pipe located in the outer pipe has a stepped part in the lower direction corresponding to a part of each inner pipe located in each connector.
8 . The method of claim 7 , wherein, at the step (e), the reducing part comprises:
a first reducing part configured with a first coupling hole assembled by inserting into the inner pipe; a second reducing part formed at an end of the first reducing part and configured with a second coupling hole for assembling ends of each connecting pipe and; and a separating part formed between the first reducing part and the second reducing part, and configured to separate the first reducing part and the second reducing part.
9 . The method of any of claims 6 , wherein, after the step (a), a step of forming a plurality of spiral parts in a spiral shape along the lengthwise direction of the inner circumference surface in the outer pipe comprises a further step so that at least a portion of the second fluid passage has a spiral shape.Cited by (0)
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