KR102223143B1 - Heat source shut-off valve for exhaust gas absorption chiller - Google Patents

Abstract

The present invention relates to a heat source blocking valve, and more specifically, to the heat source blocking valve for an exhaust gas absorption freezer, wherein the heat source blocking valve having a blocking plate axially rotated by a controller and blocking exhaust gas is installed between an outlet side and a duct of a high temperature regenerator, and air is supplied into the heat source blocking valve by using a ring blower to maintain pressure of the inside of the high temperature regenerator to be higher than pressure of the exhaust gas to completely block introduction of the exhaust gas into the high temperature regenerator.

Description

Heat source shut-off valve for exhaust gas absorption chiller {HEAT SOURCE SHUT-OFF VALVE FOR EXHAUST GAS ABSORPTION CHILLER}

The present invention relates to a heat source shut-off valve, and in particular, a heat source shut-off valve having a shut-off plate that is axially rotated by a manipulator between a discharge side of a high-temperature regenerator and a duct and blocks exhaust gas, is installed, and into the heat source shut-off valve. The present invention relates to a heat source shutoff valve for an exhaust gas absorption chiller that completely shuts off the inflow of exhaust gas into the high-temperature regenerator by supplying air using a ring blower so that the pressure inside the high-temperature regenerator is maintained higher than the pressure of the exhaust gas.

Exhaust gas temperatures generated by gas engines and gas turbines, which are most commonly used in cogeneration, are 450-550℃ for gas engines and 280℃ for gas turbines. They are used in various ways such as power generation using thermoelectric elements, heat pumps, and exhaust gas absorption chillers. In particular, the exhaust gas absorption chiller has high efficiency, proven technology, and various types of exhaust gas can be used, thus maximizing energy use efficiency by using exhaust gas heat after power generation, contributing to cost reduction and carbon dioxide emission reduction. In addition, the combined efficiency in summer of a cogeneration generator capable of producing heat and electric energy required by industries and buildings is 30-40%, but when an absorption chiller that uses exhaust gas as a heat source is used, the overall efficiency can be over 60-70%. When the supply of exhaust gas from the absorption chiller is described in more detail, the exhaust gas discharged from the engine or turbine is discharged through the duct D, as shown in FIG. 1, and a diverter valve installed in the duct D ( V) controls the inflow and shut-off of exhaust gas with a high-temperature regenerator (HG). At this time, a blower (B) is installed in the diverter valve (V), and an air curtain is installed inside the duct (D) to block exhaust gas from flowing into the high-temperature regenerator (HG). When the high-temperature regenerator (HG) is not in operation, a bypass duct (BD) that bypasses exhaust gas to the chimney is connected and installed.

In addition, the diverter valve V has a structure in which the valve is closed or opened while the metal blocking plate 3 coupled to the link 1 is in contact with the jaw 5 and is sealed or spaced apart as shown in FIG. 2. Is formed.

However, due to the high temperature of the exhaust gas, the blocking plate and the jaw are deformed by heat, and the sealing is not performed even when the valve is closed, so that the exhaust gas flows into the high-temperature heat exchanger while the absorption chiller is stopped, resulting in crystallization of the absorbent liquid. There is a problem that occurs and interferes with normal operation.

Korean Patent Publication No. 10-2005-0008964

The present invention is to solve the above problems, and a heat source shut-off valve having a shut-off plate that is axially rotated by a manipulator between the discharge side of the high-temperature regenerator and the duct and blocks exhaust gas, is installed, and the heat source shut-off valve is inside. The purpose of this is to provide a heat source shutoff valve for an exhaust gas absorption chiller that completely shuts off the inflow of exhaust gas into the high temperature regenerator by supplying air using a ring blower to keep the pressure inside the high-temperature regenerator higher than the pressure of the exhaust gas. have.

In addition, an object of the present invention is to provide a heat source shutoff valve for an exhaust gas absorption chiller that facilitates maintenance by manufacturing each component of the heat source shutoff valve so that it can be disassembled and assembled.

Features of the present invention for achieving the above object,

An absorption chiller for cooling by receiving exhaust gas discharged from an engine or a turbine through a duct to a high-temperature regenerator, and opening and closing a flow path installed between the outlet side of the high-temperature regenerator and the duct to reduce the exhaust gas to the high-temperature regenerator. A blocking assembly that blocks inflow; And a ring blower configured to block the inflow of the exhaust gas into the high temperature regenerator by introducing air having a higher pressure than the exhaust gas into the blocking assembly.

Here, the blocking assembly includes a case bolted to the duct; A diaphragm installed inside the case; A blocking body installed through the center of the diaphragm in the form of a circular tube or an angled tube so that exhaust gas is introduced, and having a first bending part bent in a "U" shape outside the lower rim; It is coupled to or spaced apart from the bottom surface of the blocking body to seal the blocking body to block or supply the inflow of exhaust gas, and is formed in a disc or angled shape, and the first bending part of the blocking body is inserted outside the rim so that it is in close contact. A blocking cover on which a second bending portion bent in a shape is formed; A shaft installed to be horizontally rotated by a bearing in the case; A manipulator installed outside the case and coupled by the shaft and a key to rotate the shaft; And a swing bracket having one end coupled to the shaft, the other end being coupled to the center of the bottom of the blocking cover, and swinging the blocking cover when the shaft is rotated according to the elevating and descending of the manipulator.

Here, in addition, the swing bracket is formed in a "digut" shape to increase strength, and a bracket body having a coupling hole into which the shaft is inserted at one end; A bracket shaft vertically installed at the other end of the bracket body and having a coupling protrusion protruding from an upper end thereof; A bracket cap formed in the form of a circular or angled bar, and a coupling groove in which the coupling protrusion of the bracket shaft is inserted into the bottom surface is formed on the bottom surface to be welded or bolted to the bottom surface of the blocking cover; And a washer coupled to the outside of the coupling protrusion of the bracket shaft and coupled to the bracket cap by welding or bolts.

Here, in addition, the coupling groove of the bracket cap has a diameter greater than the coupling protrusion of the bracket shaft so that the second bending portion of the blocking cover secures a clearance that does not interfere with the first bending portion of the blocking body when opening and closing the blocking cover. And the height is formed to be larger so that the coupling protrusion is moved up and down left and right within the coupling groove.

Here, in the bracket cap, a first reinforcing plate is welded or bolted between the blocking cover and the bracket cap to prevent deformation of the blocking cover when welding or bolted to the bottom surface of the blocking cover.

Here, the case is formed in a cylindrical or angular shape with flanges on the upper and lower surfaces, and a lower case in which the ring blower and the manipulator are installed; An intermediate case formed in a cylindrical or angular shape having flanges on the upper and lower surfaces thereof and bolted to the lower case, and in which the diaphragm, the blocking body, the blocking cover and the shaft are installed; And an upper case formed in a cylindrical or angular shape with flanges on the upper and lower surfaces and bolted to the intermediate case.

Here, in addition, the second reinforcing plate is welded or bolted to the upper surface of the blocking cover to prevent deformation.

Here again, the blocking cover is formed with a rib to prevent deformation.

According to the heat source shut-off valve for an exhaust gas absorption refrigerator according to the present invention configured as described above, a heat source shut-off valve having a shut-off plate configured as described above is axially rotated by a manipulator between the discharge side of the high-temperature regenerator and the duct, and blocks exhaust gas, By supplying air to the inside of the heat source shutoff valve by using a ring blower, the pressure inside the high-temperature regenerator is maintained higher than the pressure of the exhaust gas, completely blocking the inflow of exhaust gas into the high-temperature regenerator, and when the refrigerator is stopped, the exhaust gas is high-temperature regenerator It is possible to block the phenomenon of crystal formation in the absorbent liquid by flowing into the inside.

Further, according to the present invention, maintenance can be easily performed by manufacturing each component of the heat source shutoff valve to be disassembled and assembled.

1 is a system diagram showing a state in which a conventional exhaust gas absorption refrigerator is installed.
2 is a cross-sectional view showing the configuration of the diverter valve of FIG. 1.
3 is a system diagram showing a state in which a heat source shutoff valve for an exhaust gas absorption refrigerator according to the present invention is installed.
4 is a partial front cross-sectional view showing the configuration of a heat source shutoff valve for an exhaust gas absorption refrigerator according to the present invention.
5 is a partial cross-sectional view of a right side of FIG. 4.
6 is an exploded view of FIG. 5.
7 is a view showing a coupling relationship between a blocking body and a blocking cover among heat source blocking valves for an exhaust gas absorbing refrigerator according to the present invention.
8 is an operation explanatory view for explaining a swing operation of a shutoff cover among heat source shutoff valves for an exhaust gas absorption refrigerator according to the present invention.

Hereinafter, a configuration of a heat source shutoff valve for an exhaust gas absorption refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present specification.

3 is a schematic diagram showing a heat source shutoff valve for an exhaust gas absorbing refrigerator according to the present invention, and FIG. 4 is a partial front sectional view showing the configuration of a heat source shutoff valve for an exhaust gas absorbing refrigerator according to the present invention, and FIG. Fig. 4 is a partial cross-sectional view of the right side, Fig. 6 is an exploded view of Fig. 5, and Fig. 7 is a view showing a coupling relationship between a blocking body and a blocking cover among heat source blocking valves for an exhaust gas absorption refrigerator according to the present invention.

3 to 7, the heat source shut-off valve 100 for an exhaust gas absorption refrigerator according to the present invention includes a shut-off assembly 110 and a ring blower 120.

First, the blocking assembly 110 includes a case 111, a diaphragm 112, a blocking body 113, a blocking cover 114, a shaft 115, a manipulator 116, and a swing bracket 117. It consists of.

The case 111 is composed of a lower case 1111, an intermediate case 1113, and an upper case 1115 to enable disassembly and assembly for each part.

The lower case 1111 is formed in a cylindrical shape (or a polygonal cylinder type) with flanges (F) on the upper and lower surfaces, and is formed in a form coupled between the outlet of the high-temperature regenerator (HG) and the duct (D), and the ring blower 120 ) And the manipulator 116 are installed. At this time, one side of the lower case 1111 is provided with an inlet I through which air from the ring blower 120 is introduced.

The middle case 1113 is formed in a cylindrical shape (or a polygonal cylinder type) with flanges (F) on the upper and lower surfaces, and is bolted to the lower case 1111, and the diaphragm 112, the blocking body 113, and the blocking cover 114 And the shaft 115 is installed.

The upper case 1115 is formed in a cylindrical shape (or a polygonal cylindrical shape) having flanges F on the upper and lower surfaces thereof, and is formed in a form coupled to the duct D and bolted to the intermediate case 1113.

The diaphragm 112 is formed in a circular plate (or polygonal plate) shape and is installed in the intermediate case 1113 in a transverse direction to close the inside of the intermediate case 1113.

The blocking body 113 is installed through the center of the diaphragm 112 in the form of a circular tube (or polygonal tube) so that exhaust gas is introduced, and the first bending part 1131 bent in a "U" shape outside the lower rim is It is equipped.

The blocking cover 114 is formed in the form of a disc (or polygonal plate) to block or supply the inflow of exhaust gas by sealing the blocking body 113 by being coupled to or spaced apart from the bottom surface of the blocking body 113, and blocking outside the rim A second bending portion 1141 bent in a "U" shape is formed so that the first bending portion 1131 of the body 113 is inserted and adhered closely. At this time, in the blocking cover 114, a second reinforcing plate P2 in the form of a ring-shaped disk (or polygonal plate) is welded or bolted to prevent deformation on the upper surface, and a rib R is formed to prevent deformation. .

The shaft 115 is installed to be rotated horizontally by a bearing A in the intermediate case 1113. At this time, the bearing A and the shaft 115 are sealed to prevent leakage of exhaust gas.

The manipulator 116 is installed outside the case 111 and is coupled by the shaft 115 and the key 1161 to vertically extend and contract to rotate the shaft 115 in both directions. At this time, the manipulator 116 is applied in various ways such as linear, hydraulic, pneumatic, electric, belt type, depending on the use environment and conditions.

The swing bracket 117 is composed of a bracket body 1171, a bracket shaft 1173, a bracket cap 1175, and a washer 1177, as shown in FIGS. 6 and 7.

The bracket body 1171 is formed in a shape of a "digut" to increase strength, and has a coupling hole H into which the shaft 115 is inserted at one end.

The bracket shaft 1173 is formed in the form of a circular rod (or a polygonal rod), is vertically installed at the other end of the bracket body 1171, and a circular (or polygonal) coupling protrusion E is protruded at the top.

The bracket cap 1175 is formed in the form of a circular rod (or a polygonal rod), and a coupling groove (H) is formed on the bottom so that the coupling protrusion (E) of the bracket shaft 115 is inserted into the bottom surface, so that the blocking cover 114 It is welded or bolted to the bottom of the plate. At this time, the coupling groove (H) is a bracket shaft so that the second bending portion 1141 of the blocking cover 114 secures a gap that does not interfere with the first bending portion 1131 of the blocking body when opening and closing the blocking cover 114. The diameter and height are larger than that of the engaging protrusion E of 1173, that is, formed to have a gap g, so that the engaging protrusion E is moved up and down left and right in the engaging groove H. In addition, the bracket cap 1175 is a disk (or multi-plate) between the blocking cover 114 and the bracket cap 1175 to prevent deformation of the blocking cover 114 when welding or bolted to the bottom of the blocking cover 114 ) The shape of the first reinforcing plate (P1) is joined by welding or bolts.

The washer 1177 is coupled to the outside of the coupling protrusion E of the bracket shaft 1173 to prevent the bracket shaft 1173 and the bracket cap 1175 from being separated, and is coupled to the bracket cap 1175 by welding or bolts.

In addition, the ring blower 120 is a fixing bracket on the outside of the lower case 1111 to block the inflow of the exhaust gas into the high temperature regenerator (HG) by introducing air having a higher pressure than the exhaust gas into the blocking assembly 110. It is fixedly installed by 121 and is bolted to the inlet I of the lower case 1111 and the connection pipe 123. At this time, a flange (F) is formed in the inlet (I) and the connection pipe (123).

Hereinafter, the operation of the heat source shutoff valve for an exhaust gas absorption refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

8 is an operation explanatory view for explaining a swing operation of a shutoff cover among heat source shutoff valves for an exhaust gas absorption refrigerator according to the present invention.

First, when the manipulator 116 of the blocking assembly 110 is contracted and the shaft 115 is rotated in one direction during the operation of the high-temperature regenerator (HG), the swing bracket 117 rotates in one direction, and the blocking cover 114 is closed to the blocking body. It is rotated by 90° at 113 to maintain an open state, and the diverter valve V also maintains an open state. At this time, the ring blower 120 is not operated.

Then, the exhaust gas discharged from the engine or turbine is discharged through the duct (D), flows into the high-temperature regenerator (HG) through the duct (D) and the diverter valve (V), and then heat-exchanged, and then the shut-off assembly 110 Is discharged to the chimney through.

Conversely, when the high temperature regenerator (HG) is not in operation, when the manipulator 116 of the blocking assembly 110 is elongated and the shaft 115 is rotated in the other direction, the swing bracket 117 rotates 90° in the other direction and the blocking cover ( 114) is in close contact with the blocking body 113.

Then, the second bending portion 1141 of the blocking cover 114 is inserted into the first bending portion 1131 of the blocking body 113, at this time, the bracket cap 1175 of the swing bracket 117 is Because it is movable, the second bending portion 1141 of the blocking cover 114 is in close contact with the first bending portion 1131 of the blocking body while blocking the flow path of the exhaust gas.

And, the diverter valve (V) also maintains a closed state.

At the same time, when the ring blower 120 is operated, air having a higher pressure than the exhaust gas cannot be discharged to the upper case 1117 side due to the sealing of the blocking cover 114 and the blocking body 113 of the blocking assembly 110. , The outlet side of the high-temperature regenerator HG is completely introduced through the lower case 1111, and the pressure inside the lower case 1111 and the internal pressure of the high-temperature regenerator HG is maintained higher than the exhaust gas pressure.

In addition, a higher pressure than the exhaust gas is maintained between the high-temperature regenerator HG and the diverter valve V by the air of the ring blower 120.

In this state, when exhaust gas discharged from the engine or turbine is discharged through the duct (D), the exhaust gas is all passed to the chimney through the bypass duct (BD) because the inside of the high-temperature regenerator (HG) maintains a higher pressure. Is discharged.

The present invention may be variously modified and may take various forms, and in the detailed description of the present invention, only specific embodiments according thereto have been described. However, it should be understood that the present invention is not limited to the specific form mentioned in the detailed description, and rather, it is understood to include all modifications, equivalents, and substitutes within the spirit and scope of the present invention as defined by the appended claims. It should be.

The present invention can be applied not only to a cogeneration system, but also to an absorption chiller using exhaust gas generated from a factory and exhaust gas emitted from a ship as a heat source.

110: blocking assembly 111: case
112: diaphragm 113: blocking body
114: blocking cover 115: shaft
116: manipulator 117: swing bracket
120: ring blower B: blower
D: Duct HG: High temperature regenerator

Claims (8)

In an absorption chiller for cooling by receiving exhaust gas discharged from an engine or turbine through a high-temperature regenerator through a duct,
A blocking assembly configured to open and close a flow path installed between the outlet side of the high-temperature regenerator and the duct to block the inflow of exhaust gas into the high-temperature regenerator;
Consisting of a ring blower that blocks the inflow of exhaust gas into the high-temperature regenerator by introducing air having a higher pressure than the exhaust gas into the blocking assembly,
The blocking assembly,
A case bolted to the duct;
A diaphragm installed inside the case;
A blocking body installed through the center of the diaphragm in the form of a circular tube or an angled tube so that exhaust gas is introduced, and having a first bending part bent in a "U" shape outside the lower rim;
It is coupled to or spaced apart from the bottom surface of the blocking body to seal the blocking body to block or supply the inflow of exhaust gas, and is formed in a disc or angled shape, and the first bending part of the blocking body is inserted outside the rim so that it is in close contact. A blocking cover on which a second bending portion bent in a shape is formed;
A shaft installed to be horizontally rotated by a bearing in the case;
A manipulator installed outside the case and coupled by the shaft and a key to rotate the shaft; And
One end is coupled to the shaft, the other end is coupled to the center of the bottom of the blocking cover and includes a swing bracket for swinging the blocking cover when the shaft is rotated according to the elevating and descending of the manipulator,
The swing bracket,
A bracket body formed in a "digut" shape to increase strength and having a coupling hole at one end into which the shaft is inserted;
A bracket shaft vertically installed at the other end of the bracket body and having a coupling protrusion protruding from an upper end thereof;
A bracket cap formed in the shape of a circular or angled bar, and a coupling groove formed on a bottom surface into which a coupling protrusion of the bracket shaft is inserted is formed on a bottom surface and is welded or bolted to the bottom surface of the blocking cover; And
A heat source shut-off valve for an exhaust gas absorption chiller, characterized in that it comprises a washer coupled to the outside of the coupling protrusion of the bracket shaft and welded or bolted to the bracket cap. delete delete The method of claim 1,
The coupling groove of the bracket cap,
When opening and closing the blocking cover, the second bending portion of the blocking cover is formed to have a larger diameter and height than the engaging projection of the bracket shaft so as to secure a clearance that does not interfere with the first bending portion of the blocking body. Heat source shut-off valve for an exhaust gas absorption refrigerator, characterized in that the movement in the left and right up and down in the coupling groove. The method of claim 4,
The bracket cap,
Heat source for an exhaust gas absorption refrigerator, characterized in that a first reinforcing plate is welded or bolted between the blocking cover and the bracket cap to prevent deformation of the blocking cover when welding or bolted to the bottom of the blocking cover. Shut-off valve. The method of claim 1,
The case,
A lower case formed in a cylindrical or angular shape with flanges on the upper and lower surfaces, and in which the ring blower and the manipulator are installed;
An intermediate case formed in a cylindrical or angular shape having flanges on the upper and lower surfaces thereof and bolted to the lower case, and in which the diaphragm, the blocking body, the blocking cover, and the shaft are installed; And
A heat source shut-off valve for an exhaust gas absorption chiller, characterized in that it is formed in a cylindrical or angular shape with flanges on its upper and lower surfaces, and is formed of an upper case that is bolted to the intermediate case. The method of claim 1,
The blocking cover,
Heat source shut-off valve for an exhaust gas absorption refrigerator, characterized in that the second reinforcing plate is welded or bolted to prevent deformation on the upper surface. The method of claim 1,
The blocking cover,
Heat source shut-off valve for an exhaust gas absorption refrigerator, characterized in that the rib is formed to prevent deformation.

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