KR20110079951A - Nozzle assembly and hydrogen recirculaton ejector having the same - Google Patents

Abstract

PURPOSE: A nozzle assembly and a hydrogen recirculaton ejector having the same are provided to improve productivity due to excellent assembility of a nozzle and other components and to minimize the processing tolerance or processing deviation of a nozzle throat. CONSTITUTION: A nozzle assembly(20) includes a bracket(21), one or more nozzle accept parts(22) protruding to one side of the bracket, and one or more nozzles(23) installed in the nozzle accommodation part. The nozzle accommodation part has an accommodation space housing a nozzle thereinside. The nozzle accommodation part includes an inner nozzle body and an outer nozzle body(25). An inner side nozzle member is assembled within the outer nozzle body. A nozzle throat is formed at one end of the inner nozzle body. The inner nozzle body is made of ceramic materials.

Description

NOZZLE ASSEMBLY AND HYDROGEN RECIRCULATON EJECTOR HAVING THE SAME

The present invention relates to a nozzle assembly and a hydrogen recycle ejector including the same, and more particularly, to a nozzle assembly and a hydrogen recycle ejector capable of improving the supply and recycling efficiency of hydrogen.

As is well known, a fuel cell system using hydrogen is provided with hydrogen gas discharged from the hydrogen tank 1 to the stack 2 and supplied to the stack 2 as illustrated in FIGS. 7 and 8. The amount of hydrogen gas is controlled by the controller. The air required for the fuel cell is discharged from the compressor and supplied to the stack 2.

When supplying air and hydrogen to the stack 2, more air and hydrogen are supplied to the stack 2 than necessary for the cell reaction to secure the performance of the stack 2 and to increase the life. Unreacted hydrogen used in the stack is then recycled back to the ejector 2 in order to prevent waste of fuel and increase the efficiency of the system. In particular, the technique of recycling the unreacted hydrogen passed through the stack 2 of the fuel cell is very important for improving fuel efficiency of the fuel cell system. Thus, the hydrogen recycling structure for recycling the unreacted hydrogen to the stack inlet is shown in FIG. 7. As shown in FIG. 8, the ejector 3 has been used or the blower 4 has been used as shown in FIG.

On the other hand, the blower method has a drawback of severe power waste, severe vibration and noise, etc. Recently, research on hydrogen recycling using an ejector has been actively conducted.

The hydrogen recirculating ejector includes an ejector housing, a plurality of nozzles, and a plurality of diffusers corresponding to each nozzle, and hydrogen directly into the stack as the hydrogen supplied from the hydrogen tank 1 passes through the plurality of nozzles and the plurality of diffusers. In addition to being supplied, it is configured to recycle unreacted hydrogen in the stack 2.

However, the conventional hydrogen recirculation ejector has a disadvantage in that the productivity of the nozzle and other components are degraded due to deterioration of the assembly of the nozzle and other components, and the nozzle flow is generated when the high pressure hydrogen passes through the nozzle because the assembly of the nozzle is not robust. There was a disadvantage in that the supply efficiency of hydrogen is lowered.

In addition, the nozzle of the conventional hydrogen recycle ejector is mainly used a stainless steel material with strong hydrogen corrosion resistance, the stainless material nozzle has been mainly processed by cemented carbide tools.

However, while stainless steel nozzles have high strength, they cause abrasion of carbide tools during nozzle processing, which greatly causes deviations or tolerances in the dimensions between the nozzle products, resulting in up to 8 variations in supply flow. There was a disadvantage that occurred severely above%.

The present invention has been made in view of the above-described object, and an object of the present invention is to provide a nozzle assembly and a hydrogen recirculation ejector including the same, which can improve productivity due to excellent assembly of nozzles and other components.

In addition, an object of the present invention is to provide a nozzle assembly that can improve the supply efficiency and recycling efficiency of hydrogen by minimizing the processing tolerance or processing deviation of the nozzle and a hydrogen recycling ejector comprising the same.

The nozzle assembly according to the present invention for achieving the above object,

A mounting bracket, at least one nozzle accommodation portion protruding from one surface of the mounting bracket, at least one nozzle installed at the nozzle accommodation portion,

The nozzle consists of an inner nozzle body and an outer nozzle body, the inner nozzle member is assembled in the outer nozzle body, one end of the inner nozzle body is formed with a nozzle neck, the inner nozzle body is made of a ceramic material It is characterized by.

The supply passage is formed in the mounting bracket in a vertical direction, the supply passage is connected to the hydrogen supply tube to communicate with each other, the receiving space is formed in the inside of each of the nozzle accommodating portion is formed, the mounting bracket of the A plurality of distribution passages are provided in the supply passage, and the distribution passages are formed to communicate with the receiving spaces of the nozzle accommodation portions.

The outer nozzle body has a fitting jaw into which the inner nozzle body is fitted at one end thereof, and a hollow part is formed therein, at least one communication hole is formed at a side thereof, and a pair of annular rings are formed at both sides of the communication hole. A step is formed, and the pair of annular step is in close contact with the receiving space of the nozzle accommodating portion, whereby an annular communication space is formed around the communication hole of the outer nozzle body, the outer nozzle body through the communication space The communicator and distribution channel are characterized in that they communicate with each other.

Assembly nozzles are formed in the outer nozzle body of the nozzle, assembly grooves are formed in the nozzle accommodating portion corresponding to the assembly protrusions, and the assembly protrusions and the assembly grooves are formed in a mutually corresponding rectangular structure to form the assembly protrusions of the nozzles. It is characterized in that the fitting in the assembly groove of the nozzle receiving portion.

In addition, the hydrogen recycle ejector of the present invention,

An ejector housing having a suction chamber, a mixing chamber, a flat part, and a diffuser therein;

And a nozzle assembly having a mounting bracket mounted on the ejector housing side, at least one nozzle accommodation portion protruding from one surface of the mounting bracket, and at least one nozzle installed at the nozzle accommodation portion.

At least one assembly hole is formed on one surface of the ejector housing, and the nozzle accommodation portion is fitted to the assembly hole of the ejector housing.

The nozzle is composed of an inner nozzle body and an outer nozzle body, the inner nozzle member is assembled in the outer nozzle body,

A nozzle neck is formed at one end of the inner nozzle body, and the inner nozzle body is made of a ceramic material.

According to the present invention as described above, the present invention can minimize the processing deviation or processing tolerance of the nozzle neck by configuring the nozzle in the inner nozzle body of the ceramic material and the outer nozzle body of stainless steel material, and also relatively expensive ceramic material By minimizing the use of the manufacturing cost can be reduced.

In addition, the present invention has the advantage of improving the assembly of the nozzle and other components to improve productivity.

1 is a perspective view showing a hydrogen recycle ejector according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing a hydrogen recycle ejector according to an embodiment of the present invention.
3 is an exploded perspective view showing a nozzle assembly according to an embodiment of the present invention, which is a partial cutaway view of the nozzle receiving portion on one side.
4 is a cross-sectional view taken along line AA of FIG. 1.
FIG. 5 is a cross-sectional view taken along line BB of FIG. 4.
6 is a cross-sectional view taken along line CC of FIG. 4.
7 is a view showing a hydrogen recycle structure of a typical fuel cell using an ejector.
8 is a diagram illustrating a hydrogen recycling structure of a general fuel cell using a blower.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 illustrate a hydrogen recycle ejector and nozzle assembly according to one embodiment of the invention.

The hydrogen recycle ejector of the present invention includes an ejector housing 10 and a nozzle assembly 20 assembled into the ejector housing 10.

As shown in FIG. 2, the ejector housing 10 has a plurality of assembly holes 11 into which one nozzle accommodation portion 22 of the nozzle assembly 20 is fitted.

As shown in FIG. 4, openings 10a and 10b are formed at both ends of the ejector housing 10, and an suction chamber 12 and a contraction portion 13a and convergence are formed inside the ejector housing 10. A mixing chamber 13 having a portion, a constant portion 14 having a flat wall 14a, a diffuser 15 having a diffusion wall 15a, and the like are formed.

The suction chamber 12 is formed adjacent to the assembly hole 11, and the suction chamber 12 is configured such that the nozzle 23 and the nozzle accommodation portion 22 of the nozzle assembly 20 described later are located.

The nozzle assembly 20 is coupled to the mounting bracket 21 mounted on the ejector housing 10 side, the plurality of nozzle accommodation portions 22 formed on one side of the mounting bracket 21, and each nozzle accommodation portion 22. It includes a plurality of nozzles (23).

The supply passage 21a is formed in the vertical direction in the mounting bracket 21, and the hydrogen supply tube 29 communicates with the first passage 21a, and in particular, the hydrogen supply tube 29 is mounted by welding or the like. It is coupled to communicate with the supply passage (21a) side of the bracket (21).

The plurality of nozzle accommodating parts 22 protrude outward from one surface of the mounting bracket 21, and an accommodating space 22 a is formed in each nozzle accommodating part 22 to accommodate the nozzle 23.

As shown in FIG. 6, a plurality of distribution passages 21b and 21c extend in the nozzle receiving portion 22 in the supply passage 21a of the mounting bracket 21, and the distribution passage 21b in each nozzle. It is formed to communicate with the receiving space (22a) of the receiving portion (22).

Each nozzle 23 is composed of an inner nozzle body 24 and an outer nozzle body 25, and an inner nozzle member 24 is assembled into the outer nozzle body 25. The inner nozzle body 24 has a cylindrical shape, and a nozzle throat 24a is formed at one end thereof, and a shrinking portion 24b is formed at the rear of the nozzle neck 24a. In addition, the inner nozzle body 24 is preferably made of a ceramic material such as zirconia having excellent strength and good workability.

As such, the present invention can process the tolerance of the nozzle neck 24a to 5/1000 mm or less as the inner nozzle body 24 of the nozzle 23 is made of a ceramic material, thereby minimizing the processing tolerance or processing deviation of the nozzle. And, there is an advantage that can increase the reliability of the performance.

The outer nozzle body 25 has a fitting jaw 25a at which one end of the inner nozzle body 24 is fitted, and a hollow portion 25b is formed therein, and at least one communication hole 25c is formed at a side thereof. ) Is formed. A pair of annular steps 25f are formed on both sides of the communication hole 25c, and the pair of annular steps 25f are hermetically in close contact with the accommodation space 22a of the nozzle accommodation portion 22, thereby An annular communication space 25g is formed around the communication hole 25c of the nozzle body 25, and the communication hole 25c and the distribution passage 21b of the outer nozzle body 25 are formed through the communication space 25g. Can communicate with each other.

The communication hole 25c of the outer nozzle member 25 communicates with each distribution passage 21b. In addition, the outer nozzle body 25 is preferably made of a stainless material having a low cost and excellent strength compared to the ceramic.

As described above, the nozzle assembly 20 of the present invention comprises the nozzle 23 as the inner nozzle body 24 made of ceramic material and the outer nozzle body 25 made of stainless steel, thereby reducing the processing deviation or the processing tolerance of the nozzle neck 24a. The manufacturing cost can be reduced by minimizing and minimizing the use of relatively expensive ceramic materials.

After each nozzle 23 is accommodated in the accommodation space 22a of each nozzle receiving portion 22, the rear surface of each nozzle 23 is closed by the closing plate 26, and behind the closing plate 26 The fastener 27 is fastened, and the fastener 27 is fastened to the rear side of the nozzle accommodating portion 22 so that the nozzle 23 can be hermetically coupled to the nozzle accommodating portion 22.

Then, an assembly protrusion 25d is formed on one side of the outer nozzle body 25 of the nozzle 23, for example, on the annular step 25f side of the outer nozzle body 25, and the nozzle accommodating part corresponds to the assembly protrusion 25d. An assembly groove 22d is formed at one side of the accommodation space 22a of the 22, and in particular, the assembly protrusion 25d and the assembly groove 22d are formed in a square structure. Accordingly, the assembly protrusion 25d of the outer nozzle body 25 is easily fitted into the assembly groove 22d of the nozzle accommodation portion 22 so that the nozzle 23 can be more precisely assembled to the nozzle accommodation portion 22. In addition, there is an advantage that can effectively prevent the movement or idle rotation of the nozzle 23, which may occur when the high-pressure hydrogen passes through the nozzle 23.

The mounting plate 19 is coupled to the part where the nozzle assembly 20 is assembled on the ejector housing 10 side, and the hydrogen recycling ejector of the present invention can be installed on the stack side of the fuel cell through the mounting plate 19. have.

10: ejector housing 11: assemblyman
20: nozzle assembly 21: mounting bracket
22: nozzle receiving portion 23: nozzle
24: inner nozzle body 25: outer nozzle body

Claims (5)

A mounting bracket, at least one nozzle accommodation portion protruding from one surface of the mounting bracket, at least one nozzle installed at the nozzle accommodation portion,
The nozzle accommodating part has an accommodating space in which the nozzle is accommodated,
The nozzle consists of an inner nozzle body and an outer nozzle body, the inner nozzle member is assembled in the outer nozzle body, one end of the inner nozzle body is formed with a nozzle neck, the inner nozzle body is made of a ceramic material Nozzle assembly, characterized in that. The method of claim 1,
A supply passage is formed in a vertical direction in the mounting bracket, and a hydrogen supply tube is connected to the supply passage so as to communicate with each other. The flow passage is nozzle assembly, characterized in that formed in communication with the receiving space of each nozzle receiving portion. The method of claim 1,
The outer nozzle body has a fitting jaw into which the inner nozzle body is fitted at one end thereof, and a hollow part is formed therein, at least one communication hole is formed at a side thereof, and a pair of annular rings are formed at both sides of the communication hole. A step is formed, and the pair of annular step is in close contact with the receiving space of the nozzle accommodating portion, whereby an annular communication space is formed around the communication hole of the outer nozzle body, the outer nozzle body through the communication space Nozzle assembly characterized in that the communication hole and the distribution passage of communication with each other. The method of claim 1,
Assembly nozzles are formed in the outer nozzle body of the nozzle, assembly grooves are formed in the nozzle accommodating portion corresponding to the assembly protrusions, and the assembly protrusions and the assembly grooves are formed in a mutually corresponding rectangular structure to form the assembly protrusions of the nozzles. The nozzle assembly, characterized in that is fitted into the assembly groove of the nozzle receiving portion. An ejector housing having a suction chamber, a mixing chamber, a flat part, and a diffuser therein;
And a nozzle assembly having a mounting bracket mounted on the ejector housing side, at least one nozzle accommodation portion protruding from one surface of the mounting bracket, and at least one nozzle installed at the nozzle accommodation portion.
At least one assembly hole is formed on one surface of the ejector housing, and the nozzle accommodation portion is fitted to the assembly hole of the ejector housing.
The nozzle is composed of an inner nozzle body and an outer nozzle body, the inner nozzle member is assembled in the outer nozzle body,
A nozzle neck is formed at one end of the inner nozzle body, and the inner nozzle body is a hydrogen recycle ejector, characterized in that composed of a ceramic material.

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