CN213810591U - Double-layer sleeve type water spraying desuperheater with cold-hot separation function - Google Patents
Double-layer sleeve type water spraying desuperheater with cold-hot separation function Download PDFInfo
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- CN213810591U CN213810591U CN202022808773.6U CN202022808773U CN213810591U CN 213810591 U CN213810591 U CN 213810591U CN 202022808773 U CN202022808773 U CN 202022808773U CN 213810591 U CN213810591 U CN 213810591U
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Abstract
The utility model discloses a double-layer sleeve type water spray desuperheater with cold-hot separation, belonging to the field of cooling of power plants and relating to the boiler steam desuperheater technology; the desuperheater is used for solving the problems that stress concentration exists in the existing desuperheater except that the existing desuperheater is subjected to severe cold-heat exchange change in high-temperature steam, and the existing desuperheater is easy to break under the reaction force of high-speed steam and high-speed desuperheater; the double-layer sleeve type design is adopted, and the high-temperature-resistant silicon carbide material is adopted between the sleeve and the desuperheater water spray pipe, so that the direct contact between the desuperheater water pipe and the high-temperature steam pipe is effectively isolated, the frequent cold and hot alternating thermal stress is avoided, and the service life of the desuperheater is greatly prolonged; the nozzle back of the desuperheater is fixed by the supporting block, the desuperheater is effectively supported by the strength of the sleeve, huge reaction force caused by high-pressure desuperheater water spraying and desuperheating is offset, the strength of the spray pipe of the desuperheater can be effectively improved, and the vibration problem of the desuperheater water spraying pipe is avoided.
Description
Technical Field
The utility model belongs to power plant cooling field relates to boiler steam desuperheater technique, specifically is a cold and hot separation double-deck cover cylinder formula water spray desuperheater.
Background
At present, a flute pipe type desuperheater or a nozzle type desuperheater is generally adopted in a boiler steam desuperheater of a large-scale thermal power plant, the desuperheater runs in high-temperature steam for a long time, when the desuperheater is frequently used or is frequently operated once opened or closed, the desuperheater is in cold and hot alternate running for a long time, alternating thermal stress is inevitable, and meanwhile, due to the fact that the stress concentration problem exists unreasonably in design, a spray pipe or a nozzle of the desuperheater is prone to cracking or even breaking. The phenomenon of breakage of steam desuperheaters in different degrees can be found in the C-level or A-level overhaul process of a unit of the plant every time, and even broken fragments of the desuperheaters sometimes enter a superheater or a reheater inlet header to block a heated surface pipe, so that long-term overtemperature operation of a boiler pipe is caused, even overtemperature pipe explosion accidents occur, and great potential safety hazards are caused to safe and stable operation of the unit;
the main design defects of the existing flute tube type desuperheater are as follows: the flute tube body is provided with a plurality of small water spraying holes along the steam direction, the back surface is not provided with holes, the front strength and the back strength are inconsistent, the flute tube body is easy to break under the action of high-flow-rate steam scouring, and meanwhile, the desuperheater is positioned in high-temperature steam, and when the flow of the desuperheater is changed rapidly, the water spraying flute tube material is easy to crack under the action of alternating stress of cold and heat. In addition, the flute-shaped pipe end is inserted into the pipeline, and as shown in the following figures, if the expansion gap is not enough, the flute-shaped pipe end is easy to break; the existing nozzle type desuperheater has the defects of severe heat exchange change in high-temperature steam due to the design defects of a nozzle, and has the problem of stress concentration due to the fact that the nozzle and a spray pipe are not designed in a smooth transition mode, and the nozzle type desuperheater is easy to break under the reaction force of high-speed steam and high-speed desuperheating water.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a double-deck telescopic water spray desuperheater of cold and hot separation for solve current desuperheater receive the cold heat exchange in high temperature steam and change acutely outside, have the stress concentration problem, under the reaction force of high-speed steam and high-speed desuperheating water, very easy cracked problem takes place.
The purpose of the utility model can be realized by the following technical scheme:
a double-layer sleeve type water spray desuperheater with cold and heat separated comprises a desuperheater pipeline, wherein a steam desuperheater is installed in the desuperheater pipeline and comprises a desuperheater nozzle pipe and a desuperheater sleeve, and the desuperheater sleeve is sleeved on the desuperheater nozzle pipe;
one end of the desuperheater sleeve is welded on the inner wall of the desuperheater pipeline, and the other end of the desuperheater sleeve penetrates through the desuperheater pipeline and extends out of the desuperheater pipeline;
an end cover is fixedly arranged on one side, through which the desuperheater pipeline penetrates, of the desuperheater pipeline, a cavity is formed by the end cover and the desuperheater pipeline, and one end, extending out of the desuperheater pipeline, of the desuperheater sleeve is embedded into the cavity;
one end of the end cover is fixedly provided with a fixing pin, and the fixing pin is used for radially fixing the desuperheater nozzle pipe;
a desuperheater spray nozzle is fixedly arranged in the desuperheater spray hole;
the desuperheater spray nozzle is axially extended and provided with a water outlet at the position intersected with the desuperheating sleeve, and the water outlet is formed along the flow direction of high-temperature steam; an expansion gap is arranged between the water outlet hole and the desuperheater spray nozzle;
and a support guide block is arranged between the desuperheater sleeve and the desuperheater nozzle pipe, the support guide block is welded on the desuperheater sleeve, and the support guide block is positioned at the back of the desuperheater spray nozzle.
Furthermore, a silicon carbide heat insulation filler layer is filled between the desuperheater sleeve and the desuperheater nozzle pipe.
Further, the supporting guide block comprises a supporting seat, a damping rod, a damping sleeve, a sliding circular truncated cone, a first fixing screw, a second fixing screw, a first fixing block, a second fixing block, a first groove, a second groove, an upper top plate, a first side plate, a second side plate and a damping spring;
a damping through hole is formed in the middle of the supporting seat, and a damping rod penetrates through the inner wall of the damping through hole;
a first side plate and a second side plate are fixedly installed on one side of the supporting seat, the first side plate and the second side plate are symmetrically arranged, a cavity is formed between the first side plate and the second side plate, the shock absorption rod is embedded into the cavity, an upper top plate is fixedly installed at the upper ends of the first side plate and the second side plate, and a shock absorption spring is arranged between the upper top plate and the shock absorption rod;
the other end of the shock absorption rod is sleeved with a shock absorption sleeve, and one end of the shock absorption sleeve is connected with a sliding round table in a sliding mode.
Furthermore, two sides of the damping sleeve are provided with fixing holes; horizontal fixed orifices have all been seted up at the both ends of supporting seat, two horizontal fixed orifices all link up each other with the shock attenuation through-hole, and two horizontal fixed orifices all goes out perpendicular to shock attenuation through-hole and sets up.
Further, the first fixing block is fixedly arranged at one end of the supporting seat; the second fixed block is fixedly arranged at the other end of the supporting seat; a first fixing screw and a second fixing screw are respectively arranged in the transverse fixing holes; the first fixing screw penetrates through the first fixing block and is embedded into the transverse fixing hole; and the second fixing screw penetrates through the second fixing block and is embedded into the transverse fixing hole.
Furthermore, a first groove is formed in one side of the first fixing screw rod; a second groove is formed in one side of the second fixing screw rod; the first groove and the second groove are both hexagonal.
Furthermore, the first fixing screw rod and the second fixing screw rod are matched with the fixing hole for use.
Compared with the prior art, the beneficial effects of the utility model are that:
1. the double-layer sleeve type design is adopted, and the high-temperature-resistant silicon carbide material is adopted between the sleeve and the desuperheater water spray pipe, so that the desuperheater water spray pipe is effectively isolated from being in direct contact with the high-temperature steam pipe, frequent cold and hot alternating thermal stress is avoided, and the service life of the desuperheater is greatly prolonged.
2. The nozzle back of the desuperheater is fixed by the supporting block, the desuperheater is effectively supported by the strength of the sleeve, huge reaction force caused by high-pressure desuperheater water spraying and desuperheating is offset, the strength of the spray pipe of the desuperheater can be effectively improved, and the vibration problem of the desuperheater water spraying pipe is avoided.
3. The end part of the desuperheater water nozzle pipe adopts a fixed guide pin, so that a desuperheater spray pipe can freely expand in the sleeve; the problems of cracking and jamming of the desuperheater caused by the problem of unsmooth expansion of the original desuperheater are avoided.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
FIG. 1 is a schematic view of the structure of the desuperheater pipeline of the present invention;
FIG. 2 is a schematic view of the steam desuperheater of the present invention;
FIG. 3 is a schematic view of the structure of the supporting guide block of the present invention;
fig. 4 is a sectional view of the support guide block of the present invention.
In the figure: 1. a desuperheater pipeline; 2. a steam desuperheater; 3. a desuperheater nozzle tube; 4. a desuperheating sleeve; 5. an end cap; 6. a fixing pin; 7. a desuperheater spray nozzle; 8. supporting the guide block; 9. a silicon carbide heat insulation filler layer; 10. a supporting seat; 11. a shock-absorbing lever; 12. a shock-absorbing sleeve; 13. a sliding circular table; 14. a first fixing screw; 15. a second fixing screw; 16. a first fixed block; 17. a second fixed block; 18. a first groove; 19. a second groove; 20. an upper top plate; 21. a first side plate; 22. a second side plate; 23. a shock absorbing spring.
Detailed Description
To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings of the embodiments of the present invention are combined to clearly and completely describe the technical solutions of the embodiments of the present invention, and obviously, the described embodiments are some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Accordingly, the detailed description of the embodiments of the present invention provided in the following drawings is not intended to limit the scope of the claimed invention, but is merely representative of selected embodiments of the present invention.
As shown in fig. 1-4, a double-layer sleeve type spray desuperheater with cold and heat separation comprises a desuperheater pipeline 1, a steam desuperheater 2 is installed in the desuperheater pipeline 1, the steam desuperheater 2 comprises a desuperheater nozzle pipe 3 and a desuperheater sleeve 4, and the desuperheater sleeve 4 is sleeved on the desuperheater nozzle pipe 3;
one end of the desuperheater sleeve 4 is welded on the inner wall of the desuperheater pipeline 1, and the other end of the desuperheater sleeve 4 penetrates through the desuperheater pipeline 1 and extends out of the desuperheater pipeline 1;
an end cover 5 is fixedly installed on one side, through which the desuperheater pipeline 1 penetrates, of the desuperheater pipeline 1, the end cover 5 and the desuperheater pipeline 1 form a cavity, and one end, extending out of the desuperheater pipeline 1, of the desuperheater sleeve 4 is embedded into the cavity;
one end of the end cover 5 is fixedly provided with a fixing pin 6, and the fixing pin 6 is used for radially fixing the desuperheater nozzle pipe 3;
a desuperheater spray nozzle 7 is fixedly arranged in the desuperheater spray hole;
the desuperheater spray nozzle 7 is axially extended and provided with a water outlet at the position intersected with the desuperheating sleeve 4, and the water outlet is formed along the flow direction of high-temperature steam; an expansion gap is arranged between the water outlet hole and the desuperheater spray nozzle 7;
a supporting guide block 8 is arranged between the desuperheater sleeve 4 and the desuperheater nozzle pipe 3, the supporting guide block 8 is welded on the desuperheater sleeve 4, and the supporting guide block 8 is positioned at the back of the desuperheater spray nozzle 7; a silicon carbide heat insulation packing layer 9 is filled between the desuperheater sleeve 4 and the desuperheater nozzle pipe 3; the supporting guide block 8 comprises a supporting seat 10, a shock absorption rod 11, a shock absorption sleeve 12, a sliding circular truncated cone 13, a first fixing screw 14, a second fixing screw 15, a first fixing block 16, a second fixing block 17, a first groove 18, a second groove 19, an upper top plate 20, a first side plate 21, a second side plate 22 and a shock absorption spring 23; a damping through hole is formed in the middle of the supporting seat 10, and a damping rod 11 penetrates through the inner wall of the damping through hole; a first side plate 21 and a second side plate 22 are fixedly installed on one side of the supporting seat 10, the first side plate 21 and the second side plate 22 are symmetrically arranged, a cavity is formed between the first side plate 21 and the second side plate 22, the shock absorption rod 11 is embedded into the cavity, an upper top plate 20 is fixedly installed at the upper ends of the first side plate 21 and the second side plate 22, and a shock absorption spring 23 is arranged between the upper top plate 20 and the shock absorption rod 11; the other end of the shock absorption rod 11 is sleeved with a shock absorption sleeve 12, and one end of the shock absorption sleeve 12 is connected with a sliding circular table 13 in a sliding mode; fixing holes are formed in two sides of the damping sleeve 12; two ends of the supporting seat 10 are respectively provided with a transverse fixing hole, the two transverse fixing holes are communicated with the damping through hole, and the two transverse fixing holes are perpendicular to the damping through hole; the first fixing block 16 is fixedly arranged at one end of the supporting seat 10; the second fixed block 17 is fixedly arranged at the other end of the supporting seat 10; a first fixing screw 14 and a second fixing screw 15 are respectively arranged in the transverse fixing holes; the first fixing screw 14 penetrates through the first fixing block 16 and is embedded into the transverse fixing hole; the second fixing screw 15 penetrates through the second fixing block 17 and is embedded into the transverse fixing hole; a first groove 18 is formed in one side of the first fixing screw 14; a second groove 19 is formed in one side of the second fixing screw 15; the first groove 18 and the second groove 19 are both hexagonal; the first fixing screw 14 and the second fixing screw 15 are matched with the fixing holes for use.
The embodiment of the utility model provides a one:
(1) firstly, the stress concentration problem between the original desuperheater injection nozzle 7 and the desuperheater nozzle pipe 3 is reformed: and (3) surfacing and polishing the positions with stress concentration to enable the positions to be in smooth transition, eliminating the stress concentration problem between the desuperheater spray nozzle 7 and the desuperheater nozzle pipe 3 and enhancing the strength of the desuperheater spray nozzle 7 and the desuperheater nozzle pipe 3.
(2) And (3) polishing other edges and corners of the spray nozzle 7 of the desuperheater to smooth the edges and corners, preventing the edges and corners from generating stress concentration between the sharp edges and the desuperheater sleeve 4 in the desuperheater sleeve 4 to damage the inner wall of the desuperheater sleeve 4, and welding a support guide block 8 on the back of the spray nozzle 7 of the desuperheater and polishing the back smoothly.
(3) The temperature reduction sleeve 4 made of the high-alloy heat-resistant steel pipe 12Cr1MoVG or T91/T92 is not suitable to be made of a stainless steel pipe because the expansion coefficient of the high-temperature-resistant stainless steel pipe is larger, and the length of the stainless steel pipe is determined according to the diameter of the pipeline 1 of the original steam desuperheater 2.
(4) The inner diameter of the desuperheater sleeve 4 is selected according to the maximum size of the desuperheater nozzle pipe 3 and the desuperheater injection nozzle 7, so that the desuperheater nozzle pipe 3 can be arranged in the desuperheater sleeve 4, but an expansion gap of at least 0.5mm is reserved between the maximum size of the desuperheater nozzle pipe 3 and the inner wall of the desuperheater sleeve 4.
(5) After the steam desuperheater 2 is installed in the desuperheater sleeve 4, a hole is formed in the desuperheater sleeve 4 at the position corresponding to the desuperheater spray nozzle 7, and therefore when the desuperheater spray nozzle 7 works, the sprayed desuperheater water can be sprayed out of the desuperheater sleeve 4 and is not affected by the desuperheater sleeve 4.
(6) And a silicon carbide casting material is filled in a gap between the desuperheater sleeve 4 and the desuperheater nozzle pipe 3 and is used for isolating the desuperheater nozzle pipe 3 and the desuperheater sleeve 4 and reducing heat exchange between the desuperheater nozzle pipe 3 and the desuperheater sleeve 4.
(7) The temperature reducing sleeve 4 is firmly welded with the big end and the small end at the root part of the original nozzle pipe 3 of the temperature reducer.
(8) The open pore of the steam desuperheater 2 installation position in the original desuperheater pipeline 1 is subjected to reaming treatment, so that the nozzle pipe 3 of the desuperheater can freely stretch in the open pore of the desuperheater sleeve 4, and the fit clearance is about 0.25 mm.
(9) Welding end cover 5 on desuperheater pipeline 1 both at the afterbody of desuperheater nozzle pipe 3 to at the fixed pin 6 of 5 middle welding of end cover, fixed pin 6 is used for fixed desuperheater nozzle pipe 3 tip, prevents the vibration of steam desuperheater 2, plays the inflation guide effect to desuperheater nozzle pipe 3 simultaneously.
The embodiment of the utility model provides a two:
in order to ensure that the nozzle pipe 3 of the desuperheater does not generate severe alternating thermal stress or the generated alternating thermal stress is smaller, a cold-hot separation sleeve type nozzle desuperheater can be designed, the superheater or reheater desuperheater is designed into a nozzle type, namely a Molok nozzle, 1 or more desuperheater spray nozzles 7 can be configured according to the maximum desuperheating water flow rate designed by the original desuperheating water system according to the number of the desuperheater spray nozzles 7, meanwhile, a thick-wall type desuperheating sleeve 4 is arranged outside the desuperheater spray nozzles 7 and the desuperheater nozzle pipe 3, materials are selected according to the ambient steam temperature, and holes are formed in the positions, corresponding to the desuperheater spray nozzles 7, of the desuperheater spray water into a high-temperature steam medium from the holes, so that the purpose of desuperheating can be achieved; in order to prevent the steam desuperheater 2 from vibrating in operation and avoid the expansion from being blocked, and to increase the strength of the steam desuperheater 2, the steam desuperheater 2 is further designed as follows:
(1) in order to prevent the expansion of the temperature reducing sleeve 4 from being blocked, one end of the temperature reducing sleeve 4 is welded and fixed, the other end of the temperature reducing sleeve 4 needs to extend to the outside of the temperature reducer pipeline 1 and needs to be reamed to keep the temperature reducer pipeline 1 capable of freely expanding, and an end cover 5 is arranged outside the temperature reducer pipeline 1 to seal the temperature reducer pipeline 1;
(2) the outer end cap 5 of the desuperheater piping 1 is centrally drilled and provided with a fixing pin 6, the fixing pin 6 is used to radially fix the desuperheater nozzle pipe 3 while axially keeping it free to expand,
(3) the temperature reducing sleeve 4 at the nozzle position of the temperature reducer is provided with a hole along the flow direction of the high-temperature steam, and a transverse expansion gap of the nozzle is reserved, so that the problem that the expansion of the spray nozzle 7 of the temperature reducer is blocked in the running process is solved.
(4) For preventing the vibration of the nozzle pipe 3 of the desuperheater, the back of the spray nozzle 7 of the desuperheater is provided with a support guide block 8 which is welded on the back of the spray nozzle 7 of the desuperheater in a way of being against the water spray direction of the nozzle, so that the spray nozzle 7 of the desuperheater supports the spray nozzle 7 of the desuperheater through an outer sleeve pipe when spraying water, and counteraction force during water spraying is counteracted, thus not only preventing the vibration cracking of the nozzle pipe 3 of the desuperheater, but also enabling the nozzle pipe to transversely expand freely in the desuperheater sleeve 4.
(5) In order to reduce heat transfer between the desuperheater nozzle pipe 3 and the desuperheater sleeve 4 as much as possible, a silicon carbide heat insulation packing layer 9 is filled between the desuperheater nozzle pipe 3 and the desuperheater sleeve 4, the silicon carbide material has extremely strong heat shock resistance and heat loss resistance and high wear resistance, and the silicon carbide granular material is used to ensure that the silicon carbide heat insulation packing layer 9 does not deform at the temperature of more than 1500 ℃, so that reliable isolation between the inside and the outside is ensured; through the design, the direct contact between the desuperheater nozzle pipe 3 and the desuperheater injection nozzle 7 and a high-temperature steam medium flowing outside the desuperheater sleeve 4 to generate heat convection can be avoided, and accordingly the destructive effect of thermal stress generated by frequent cold and hot alternate changes of the desuperheater nozzle pipe 3 and the desuperheater injection nozzle 7 is avoided.
In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.
Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.
The specific meaning of the above terms in the present invention can be understood in specific cases for a person of ordinary skill in the art; the preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not exhaustive and do not limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.
Claims (7)
1. A double-layer sleeve type water spray desuperheater with cold and heat separated is characterized by comprising a desuperheater pipeline (1), wherein a steam desuperheater (2) is installed in the desuperheater pipeline (1), the steam desuperheater (2) comprises a desuperheater nozzle pipe (3) and a desuperheater sleeve (4), and the desuperheater sleeve (4) is sleeved on the desuperheater nozzle pipe (3);
one end of the temperature reducing sleeve (4) is welded on the inner wall of the temperature reducer pipeline (1), and the other end of the temperature reducing sleeve (4) penetrates through the temperature reducer pipeline (1) and extends out of the temperature reducer pipeline (1);
an end cover (5) is fixedly installed on one side, through which the desuperheater pipeline (1) penetrates, the end cover (5) and the desuperheater pipeline (1) form a cavity, and one end, extending out of the desuperheater pipeline (1), of the desuperheater sleeve (4) is embedded into the cavity;
one end of the end cover (5) is fixedly provided with a fixing pin (6), and the fixing pin (6) is used for radially fixing the desuperheater nozzle pipe (3);
a desuperheater spray nozzle (7) is fixedly arranged in the desuperheater spray hole;
a water outlet is formed in the position where the extension line of the axial direction of the desuperheater spray nozzle (7) is intersected with the desuperheating sleeve (4), and the water outlet is formed along the steam flow direction; an expansion gap is arranged between the water outlet hole and the desuperheater spray nozzle (7);
and a supporting guide block (8) is arranged between the desuperheater sleeve (4) and the desuperheater nozzle pipe (3), the supporting guide block (8) is welded on the desuperheater sleeve (4), and the supporting guide block (8) is positioned at the back of the desuperheater spray nozzle (7).
2. A cold-hot separated double-deck telescopic water spray desuperheater according to claim 1, wherein a silicon carbide heat insulation packing layer (9) is filled between the desuperheater sleeve (4) and a desuperheater nozzle pipe (3).
3. The double-deck telescopic type water spray desuperheater of claim 1, wherein the supporting guide block (8) comprises a supporting seat (10), a shock absorption rod (11), a shock absorption sleeve (12), a sliding circular truncated cone (13), a first fixing screw (14), a second fixing screw (15), a first fixing block (16), a second fixing block (17), a first groove (18), a second groove (19), an upper top plate (20), a first side plate (21), a second side plate (22) and a shock absorption spring (23);
a damping through hole is formed in the middle of the supporting seat (10), and a damping rod (11) penetrates through the inner wall of the damping through hole;
a first side plate (21) and a second side plate (22) are fixedly mounted on one side of the supporting seat (10), the first side plate (21) and the second side plate (22) are symmetrically arranged, a cavity is formed between the first side plate (21) and the second side plate (22), one end of the shock absorption rod (11) is embedded into the cavity, an upper top plate (20) is fixedly mounted at the upper ends of the first side plate (21) and the second side plate (22), and a shock absorption spring (23) is arranged between the upper top plate (20) and the shock absorption rod (11);
the other end of the shock absorption rod (11) is sleeved with a shock absorption sleeve (12), and one end of the shock absorption sleeve (12) is connected with a sliding round table (13) in a sliding mode.
4. A cold-hot separated double-layer sleeve type water spray desuperheater according to claim 3, wherein two sides of the damping sleeve (12) are provided with fixing holes; horizontal fixing holes are formed in the two ends of the supporting seat (10), the two horizontal fixing holes are communicated with the damping through holes, and the two horizontal fixing holes are perpendicular to the damping through holes.
5. A cold-hot separation double-layer telescopic water spray desuperheater according to claim 4, wherein the first fixing block (16) is fixedly installed at one end of the supporting seat (10); the second fixing block (17) is fixedly arranged at the other end of the supporting seat (10); a first fixing screw (14) and a second fixing screw (15) are respectively arranged in the transverse fixing holes; the first fixing screw (14) penetrates through the first fixing block (16) and is embedded into the transverse fixing hole; and the second fixing screw (15) penetrates through the second fixing block (17) and is embedded into the transverse fixing hole.
6. A cold-hot separation double-layer sleeve type water spray desuperheater according to claim 5, wherein a first groove (18) is formed in one side of the first fixing screw rod (14); a second groove (19) is formed in one side of the second fixing screw rod (15); the first groove (18) and the second groove (19) are both hexagonal.
7. A cold-hot separation double-layer telescopic water spray desuperheater according to claim 6, wherein the first fixing screw (14) and the second fixing screw (15) are matched with the fixing holes.
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN112303614A (en) * | 2020-11-26 | 2021-02-02 | 淮浙煤电有限责任公司凤台发电分公司 | Double-layer sleeve type water spraying desuperheater with cold-hot separation function |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN112303614A (en) * | 2020-11-26 | 2021-02-02 | 淮浙煤电有限责任公司凤台发电分公司 | Double-layer sleeve type water spraying desuperheater with cold-hot separation function |
CN112303614B (en) * | 2020-11-26 | 2024-09-27 | 淮浙煤电有限责任公司凤台发电分公司 | Cold-hot separation double-layer sleeve type water spraying attemperator |
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