TURBO-BLOWER HAVING COMPLEX COOLING STRUCTURE FOR FUEL CELL

Abstract

The present invention relates to a turbo-blower having a complex cooling structure for a fuel cell, and more specifically, to a turbo-blower having a complex cooling structure for a fuel cell, the turbo-blower providing improved efficiency and durability of an impeller means by inhibiting a temperature rise through cooling of the impeller means that generates high-pressure air, by a cooling structure configured to simultaneously utilize both an air-cooling method and a water-cooling method.

Claims

1. A turbo-blower (1) having a complex cooling structure for a fuel cell, for solving a problem (short service life or a decrease in efficiency) of the turbo-blower for a fuel cell due to high heat, by maximizing a cooling effect of the turbo-blower for a fuel cell and improving efficiency and durability of the turbo-blower for a fuel cell, through cooling an impeller means (200), which generates compressed air, by a cooling method of utilizing both air-cooling and water-cooling simultaneously, the turbo-blower comprising: a blower casing means (100) that guides flow and discharge of suctioned air; and an impeller means (200) that is positioned inside the blower casing means (100) and is coupled to the blower casing means (100) and generates inflow and flow of air, wherein the blower casing means (100) that guides air suctioned inside to a specific path to inhibit a temperature rise of the impeller means (200) is configured to include: an air suction duct (110) that allows air to be suctioned inside; an air flow guiding cover (120) that is formed to have a curved surface, is air-tightly coupled to the impeller means (200) at a neighboring position, and guides air suctioned inside to the impeller means (200); an air emitting duct (130) that causes air subjected to a pressure rise through the impeller means (200) to be discharged to a fuel cell stack; a suctioned air securing portion (140) that causes an amount of air suctioned inside the blower casing means (100) to be secured; an impeller means air-cooling portion (150) that cools the impeller means (200) by using flow of air suctioned inside the blower casing means (100) by the impeller means (200); an impeller means water-cooling unit (160) that is formed to neighbor the impeller means (200), cools the impeller means (200) by using flow of cooling water supplied from outside, and has a cooling-water inflowing/circulating groove (161); a first air flow path (170) that is generated by the air suction duct (110), the impeller means air-cooling portion (150), and the air flow guiding cover (120); a second air flow path (180) that is generated by the air suction duct (110), the suctioned air securing portion (140), and the air flow guiding cover (120); and an air circulating chamber (190) that is formed by the air flow guiding cover (120) and causes air suctioned through the first air flow path (170) and the second air flow path (180) to easily flow, wherein the turbo-blower for a fuel cell is configured to maximize efficiency and durability by decreasing a temperature rise of the impeller means (200) rotating at a high speed and guiding the air suctioned inside the blower casing means (100) to a specific path as described above, wherein the impeller means (200) that causes air to be suctioned inside the blower casing means (100) is configured to include: a stator (210); a rotor (220); and an impeller (230), wherein suctioned air is compressed, and compressed air is delivered to the fuel cell stack, and wherein a decrease in temperature rise, efficiency, and durability of the impeller means (200) rotating at a high speed are maximized by inhibiting a temperature rise inside the blower casing means (100) by the cooling method of utilizing both air-cooling and water-cooling simultaneously and further promoting a thermal equilibrium state.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0029] The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which:

[0030] FIG. 1 illustrates a configurational diagram of the turbo-blower having a complex cooling structure for a fuel cell as the present invention;

[0031] FIG. 2 illustrates a perspective view of a state of the turbo-blower having a complex cooling structure for a fuel cell as the present invention;

[0032] FIG. 3 illustrates a cross sectional view of the turbo-blower having a complex cooling structure for a fuel cell as the present invention; and

[0033] FIG. 4 is a flow chart briefly illustrating an operation and a flow of air of the turbo-blower having a complex cooling structure for a fuel cell as the present invention.

REFERENCE SIGNS LIST

[0034] 1: a turbo-blower having a complex cooling structure for a fuel cell [0035] 100: blower casing means [0036] 110: air suction duct [0037] 120: air flow guiding cover [0038] 130: air emitting duct [0039] 140: suctioned air securing portion [0040] 150: impeller means air-cooling portion [0041] 160: impeller means water-cooling unit [0042] 161: cooling-water inflowing/circulating groove [0043] 170: first air flow path [0044] 180: second air flow path [0045] 190: air circulating chamber [0046] 200: impeller means [0047] 210: stator [0048] 220: rotor [0049] 230: impeller [0050] S100: impeller means operating step [0051] S200: air suctioning step [0052] S300: air flowing step [0053] S310: first air flow path generating step [0054] S320: second air flow path generating step [0055] S400: impeller means cooling step [0056] S500: air compressing step [0057] S600: compressed air emitting step [0058] S700: compressed air supplying step

BEST MODE

Mode for Invention

[0059] Hereinafter, a function, a configuration, and an operation of a turbo-blower having a complex cooling structure for a fuel cell as the present invention will be described in detail with reference to the accompanying drawings.

[0060] FIG. 1 illustrates a configurational diagram of the turbo-blower having a complex cooling structure for a fuel cell as the present invention. FIG. 2 illustrates a perspective view of a state of the turbo-blower having a complex cooling structure for a fuel cell as the present invention. FIG. 3 illustrates a cross sectional view of the turbo-blower having a complex cooling structure for a fuel cell as the present invention.

[0061] As illustrated in FIGS. 1 to 3, according to the present invention, a turbo-blower (1) having a complex cooling structure for a fuel cell is configured to include:

[0062] a blower casing means (100) that guides flow and discharge of suctioned air; and

[0063] an impeller means (200) that is positioned inside the blower casing means (100) and is coupled to the blower casing means (100) and generates inflow and flow of air, and

[0064] the blower casing means (100) is configured to include: an impeller means air-cooling portion (150) that cools the impeller means (200) by using flow of air suctioned inside the blower casing means (100) by the impeller means (200); and an impeller means water-cooling unit (160) that is formed to neighbor the impeller means (200) and cools the impeller means (200) by using flow of cooling water supplied from outside such that a decrease in temperature rise, efficiency, and durability of the impeller means (200) rotating at a high speed are maximized.

[0065] That is, the present invention provides a turbo-blower for a fuel cell which enables oxygen to be supplied to a fuel cell stack, for solving a problem (short service life or a decrease in efficiency) of the turbo-blower for a fuel cell due to high heat, by maximizing a cooling effect of the turbo-blower for a fuel cell and improving efficiency and durability of the turbo-blower for a fuel cell through cooling an impeller means (200), which generates compressed air, by a cooling method of utilizing both air-cooling and water-cooling simultaneously.

[0066] More specifically, the blower casing means (100) that guides air suctioned inside by the impeller means (200) to a specific path to inhibit a temperature rise of the impeller means (200) is configured to include, as illustrated in FIG. 3,

[0067] an air suction duct (110) that allows air to be suctioned inside;

[0068] an air flow guiding cover (120) that is formed to have a curved surface, is air-tightly coupled to the impeller means (200) at a neighboring position, and guides air suctioned inside to the impeller means (200);

[0069] an air emitting duct (130) that causes air subjected to a pressure rise through the impeller means (200) to be discharged to a fuel cell stack;

[0070] a suctioned air securing portion (140) that causes an amount of air suctioned inside the blower casing means (100) to be secured;

[0071] an impeller means air-cooling portion (150) that cools the impeller means (200) by using flow of air suctioned inside the blower casing means (100) by the impeller means (200);

[0072] an impeller means water-cooling unit (160) that is formed to neighbor the impeller means (200), cools the impeller means (200) by using flow of cooling water supplied from outside, and has a cooling-water inflowing/circulating groove (161);

[0073] a first air flow path (170) that is generated by the air suction duct (110), the impeller means air-cooling portion (150), and the air flow guiding cover (120);

[0074] a second air flow path (180) that is generated by the air suction duct (110), the suctioned air securing portion (140), and the air flow guiding cover (120); and

[0075] an air circulating chamber (190) that is formed by the air flow guiding cover (120) and causes air suctioned through the first air flow path (170) and the second air flow path (180) to easily flow.

[0076] The turbo-blower for a fuel cell is configured to maximize efficiency and durability by decreasing a temperature rise of the impeller means (200) rotating at a high speed and guiding the air suctioned inside the blower casing means (100) to a specific path as described above.

[0077] That is, as described above, the efficiency and durability of the turbo-blower for a fuel cell are improved by inhibiting a temperature rise inside the blower casing means (100) by the cooling method of utilizing both air-cooling and water-cooling simultaneously and further promoting a thermal equilibrium state in the turbo-blower for a fuel cell.

[0078] An organic coupling relationship of the blower casing means (100) of the present invention together with coupling to the impeller means (200) maximizes an effect that the turbo-blower for a fuel cell can exhibit.

[0079] For example, firstly, forming of the impeller means air-cooling portion (150) allows air suctioned into the air suction duct (110) by the impeller means (200) to come into contact with the impeller means (200) and the impeller means water-cooling unit (160) and inhibits a temperature rise of the impeller means (200) and the impeller means water-cooling unit (160).

[0080] That is, suctioned air is divided into two streams (first air flow path (170) and second air flow path (180)) by the impeller means air-cooling portion (150) and the suctioned air securing portion (140) and cools the impeller means (200) through the first air flow path (170) and the impeller means water-cooling unit (160) through the second air flow path (180) to inhibit a temperature rise.

[0081] Secondly, the impeller means water-cooling unit (160) formed to neighbor the impeller means (200) inhibits a temperature rise of the impeller means (200), together with the impeller means air-cooling portion (150).

[0082] That is, the impeller means air-cooling portion (150) cools a stator (210) and a rotor (220) of the impeller means (200) by using suctioned air, and the impeller means water-cooling unit (160) cools the stator (210) of the impeller means (200) by using cooling water.

[0083] Air suctioned into the second air flow path (180) through the air suction duct (110) and the suctioned air securing portion (140) cools inner walls of the impeller means water-cooling unit (160) and the blower casing means (100) and inhibits a temperature rise of the impeller means (200) and the impeller means water-cooling unit (160).

[0084] Thirdly, the air flow guiding cover (120) that is formed to have a curved surface which appears to surround an impeller (230) is air-tightly coupled to the impeller means (200) at a neighboring position of the impeller (230) of the impeller means (200) coupled to the air suction duct (110) in an opposite direction such that the impeller means air-cooling portion (150) and the impeller means water-cooling unit (160) are smoothly operated. In this manner, noise is reduced, and air is to be suctioned only through the air suction duct (110).

[0085] In addition, the air flow guiding cover (120) is a configurational element used to generate the first air flow path (170) and the second air flow path (180) and guides air suctioned through the first air flow path (170) and the second air flow path (180) to easily flow into the impeller (230).

[0086] Fourthly, in order to overcome a problem of a lack of an amount of air which has to flow into the impeller (230) due to a positional relationship between the impeller (230) of the impeller means (200) and the air suction duct (110) of the blower casing means (100), a sufficient amount of air which flows into the impeller 230 is to be secured by generating a second air flow path (170) through the suctioned air securing portion (140).

[0087] In another words, positions, at which the impeller (230) and the air suction duct (110) are formed, are both edges of the blower casing means (100), and thus the suctioned air securing portion (140) for smooth flowing of the suctioned air and for securing of the amount of air is formed.

[0088] That is, the present invention focuses on a cooling method of the impeller means (200) as a part of maximizing efficiency and durability of the turbo-blower for a fuel cell such that a cooling structure that can utilize both air-cooling and water-cooling simultaneously by organic coupling of the blower casing means (100) and the impeller means (200) together to cool the impeller means (200).

[0089] Further, in the turbo-blower (1) having a complex cooling structure for a fuel cell as the present invention, air suctioned through the air suction duct (110) absorbs heat from the impeller means (200) to cool the impeller means (200) while passing through the impeller means (200), and active molecular motion of air is promoted due to the absorbed heat, and thereby air is to easily flow toward the impeller (230).

[0090] That is, the present invention inhibits the temperature rise of the impeller means (200), decreases noise, and maximizes efficiency and durability of the turbo-blower for a fuel cell.

[0091] Meanwhile, the impeller means (200) that suctions air inside the blower casing means (100) is configured to include:

[0092] the stator (210);

[0093] the rotor (220); and

[0094] the impeller (230), so as to have the same configuration as a high-speed motor formed in a turbo-blower for a fuel cell in the related art.

[0095] The present invention is a technology for cooling the impeller means (200) through the organic coupling of the blower casing means (100) and the impeller means (200), and, particularly, organic coupling of the blower casing means (100) to which the impeller means (200) is coupled, and the present invention is not a technology related to the impeller means (200), and thus the detailed description of the technology related to the impeller means (200) is to be omitted.

[0096] Meanwhile, to briefly describe the operation and the flow of air of the turbo-blower (1) having a complex cooling structure for a fuel cell with reference to FIG. 4, the impeller means (200) rotates by energy supplied from outside ( S100, impeller means operating step), and the impeller means (200) rotating at a high speed causes air to be suctioned inside the blower casing means (100) ( S200, air suctioning step).

[0097] Air suctioned inside the blower casing means (100) flows by being divided into two streams ( S300, air flowing step), divided air flows along the first air flow path (170) and the second air flow path (180) ( S310 and S320, first air flow path generating step and second air flow path generating step), and the impeller means (200) is cooled ( S400, impeller means cooling step).

[0098] The air flowing along each of the first air flow path (170) and the second air flow path (180) is compressed by the impeller (230) ( S500, air compressing step), the compressed air is discharged by the air emitting duct (130) ( S600 compressed air emitting step), and the compressed air is supplied to the fuel cell stack coupled to the air emitting duct (130) ( S700, compressed air supplying step)

[0099] Here, the impeller means water-cooling unit (160) continuously performs cooling of the impeller means (200) by utilizing water-cooling in a process from the impeller means operating step (S100) to the compressed air supplying step (S700) such that the impeller means (200) is cooled.

[0100] That is, the present invention relates to the turbo-blower for a fuel cell which compresses suctioned air and transfers compressed air to the fuel cell stack.

[0101] As described above, the present invention is not limited to the described embodiment, and it is obvious for those who have common knowledge in the art to variously modify and change the present invention without departing from the idea and the scope of the present invention.

[0102] Hence, since the present invention can be realized as various embodiments without departing from the technical idea or the major feature, the embodiments of the present invention are only provided as simple examples and are not to be construed narrowly but can be variously modified.

INDUSTRIAL APPLICABILITY

[0103] The present invention relates to a turbo-blower having a complex cooling structure for a fuel cell, it can be applied to a manufacturing business of manufacturing turbo-blowers and a sales business thereof, particularly, to an industry related to a turbo-blower for a fuel cell for supplying compressed air to a fuel cell stack, and further, it can contribute to an improvement in various industrial fields of general industries or the like in which compressed air is used.