CN214700637U - Novel energy-saving low-carbon emission-reducing boiler - Google Patents

Abstract

The utility model relates to an energy-saving boiler technical field especially relates to a novel energy-conserving low carbon emission reduction boiler, and the bottom of having solved the energy-saving boiler among the prior art all is through four supporting leg fixed connection usually, can cause the unstability of the during operation of furnace body, and some energy-saving boilers simultaneously adopt the bolt to fix, are not convenient for remove, and waste time and energy when dismantling the boiler problem. The utility model provides a novel energy-conserving low carbon emission reduction boiler, includes the boiler body, L type spout has all been seted up to four corners of boiler body. The utility model discloses in the adjustability that proposes through realizing the supporting leg, when removing the supporting leg to suitable position, the block is fixed the supporting leg between reuse spacing groove and the stopper, not only has very high flexibility, is convenient for remove the boiler body simultaneously more, is convenient for dismantle between boiler body and the base simultaneously, has also accelerated the installation of boiler body equally, has realized the effect that the boiler body is convenient for install.

Description

Novel energy-saving low-carbon emission-reducing boiler

Technical Field

The utility model relates to an energy-saving boiler technical field especially relates to a novel energy-conserving low carbon emission reduction boiler.

Background

An energy-saving boiler is also called a waste heat boiler, and is a boiler which heats water to a certain working medium by using waste gas, waste materials or waste liquid in various industrial processes and heat generated after combustible substances are combusted. The waste heat recovery of the waste heat boiler can produce hot water or steam for other sections, wherein the energy-saving and emission-reducing boiler generally uses natural gas and liquefied gas as fuels and is widely applied in life.

The bottom of the energy-saving boiler in the prior art is usually connected through four supporting legs, if the traditional mode is not fixed, the instability of the working time of the boiler body can be caused, the service life of the boiler can be influenced for a long time, the energy-saving boiler with the traditional mode is fixed by bolts, certain defects exist, the boiler is inconvenient to move, and time and labor are wasted when the boiler is detached.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a novel energy-conserving low carbon emission reduction boiler, the bottom of having solved the energy-conserving boiler among the prior art all is connected through four supporting legs usually, if this kind of traditional mode is not fixed, not only can cause the during operation of furnace body unstable, and can influence the life of boiler up and down, the energy-conserving boiler that has simultaneously adopts the bolt to fix, there is certain drawback equally, be not convenient for remove, and waste time and energy when dismantling the boiler problem.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a novel energy-conserving low carbon emission reduction boiler, including the boiler body, L type spout has all been seted up to four corners of boiler body, one side that boiler body is close to four L type spouts respectively all is equipped with the supporting leg, and the supporting leg passes through sliding connection between slider and the L type spout, all be connected with the telescopic link through the rotation of torsional spring pivot on the both sides outer wall of supporting leg, the upper portion and the equal fixedly connected with fixed block in lower part of telescopic link, and the cover is equipped with the extrusion spring on the telescopic link, and the both ends of extrusion spring respectively with two fixed blocks between fixed connection, wherein one of keeping away from the supporting leg of telescopic link serves fixedly connected with stopper, all set up the spacing groove that cooperation stopper used on the horizontal segment inner wall of L type spout and the vertical section inner wall.

Preferably, the bottom of boiler body is equipped with the base, all be equipped with between per two in four supporting legs with the bottom fixed connection's of boiler body connecting block, four connecting blocks are the annular array along the bottom of boiler body and distribute, the spread groove has all been seted up on four connecting blocks, and the bottom of four connecting blocks all is equipped with the kelly that the cooperation spread groove used to fixed connection between the bottom of four kellies all and the top of base, wherein four kellies are the annular array and distributes along the top of base.

Preferably, the upper portion both sides of four kellies all are connected with the fixture block through the rotation of torsional spring pivot, and the draw-in groove that the cooperation fixture block used is all seted up to the inner wall both sides of spread groove.

Preferably, the two sides of the outer walls of the four clamping rods are fixedly connected with the top of the base through reinforcing ribs.

Preferably, the tops of all strengthening ribs all are connected with branch through the round pin axle rotation, and the reinforcing groove that cooperation branch used is seted up to the bottom of connecting block.

Preferably, the four L-shaped sliding grooves are in clearance fit with the four sliding blocks respectively.

The utility model discloses possess following beneficial effect at least:

1. when the novel energy-saving low-carbon emission-reducing boiler is used, firstly, supporting legs at four corners of the bottom of a boiler body slide in an L-shaped chute by utilizing a slide block and move to the horizontal section position of the L-shaped chute, then, a telescopic rod corresponding to a limiting groove in the horizontal section of the L-shaped chute is rotated, meanwhile, the telescopic rod is compressed by utilizing the mutual matching between the telescopic rod and an extrusion spring, when the top of the telescopic rod and the limiting groove are positioned in the same vertical direction, the compression of the telescopic rod is stopped, the limiting block and the limiting groove are mutually clamped by utilizing the elasticity of the extrusion spring for limiting the supporting legs, compared with the prior art, the bottom of the energy-saving boiler is generally connected by four supporting legs, if the traditional mode is not fixed, the instability of the working of a boiler body can be caused, and the service life of the boiler can be influenced for a long time, the utility model discloses in the adjustability that proposes through realizing the supporting leg, when removing the supporting leg to suitable position, the block is fixed the supporting leg between spacing groove and the stopper of recycling, not only has very high flexibility, is convenient for remove the boiler body simultaneously more.

2. Through the mutual block between the draw-in groove in four connecting blocks of boiler body bottom and the fixture block of four kelly both sides, not only strengthened the steadiness of whole boiler body, simultaneously through the mode of mutual block, be convenient for more dismantle between boiler body and the base, also accelerated boiler body's installation work equally, realized the boiler body effect of being convenient for install.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without any creative effort.

FIG. 1 is an overall front view of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a sliding structure view of the support leg of the present invention;

fig. 4 is an enlarged view of the area a of the present invention.

In the figure: 1. a boiler body; 2. an L-shaped chute; 3. a limiting groove; 4. supporting legs; 5. a slider; 6. a telescopic rod; 7. a compression spring; 8. a fixed block; 9. a limiting block; 10. a base; 11. connecting blocks; 12. connecting grooves; 13. a card slot; 14. a clamping rod; 15. a clamping block; 16. reinforcing ribs; 17. a strut; 18. and a reinforcing groove.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-4, a novel energy-saving low-carbon emission-reducing boiler comprises a boiler body 1, wherein L-shaped chutes 2 are respectively formed at four corners of the boiler body 1, supporting legs 4 are respectively arranged at one side of the boiler body 1 close to the four L-shaped chutes 2, the supporting legs 4 are slidably connected with the L-shaped chutes 2 through sliders 5, telescopic rods 6 are rotatably connected to outer walls of two sides of the supporting legs 4 through torsion spring rotating shafts, fixed blocks 8 are fixedly connected to upper portions and lower portions of the telescopic rods 6, extrusion springs 7 are sleeved on the telescopic rods 6, two ends of the extrusion springs 7 are respectively fixedly connected with the two fixed blocks 8, wherein a limit block 9 is fixedly connected to one end of the telescopic rod 6 far away from the supporting legs 4, and limit grooves 3 matched with the limit block 9 are respectively formed on inner walls of a horizontal section and a vertical section of the L-shaped chutes 2, utilize the portable effect of supporting leg 4, not only be convenient for remove boiler body 1 more, can adapt to not through the boiler service environment of height through contracting supporting leg 4, have very high flexibility.

The scheme has the following working processes:

at first utilize slider 5 to slide in L type spout 2 with supporting leg 4 of four corners in 1 bottom of boiler body, remove to the horizontal segment position of L type spout 2, will rotate with the telescopic link 6 that the spacing groove 3 in the horizontal segment corresponds in the L type spout 2 after that, utilize mutually supporting between telescopic link 6 and the extrusion spring 7 simultaneously, compress telescopic link 6, when the top of telescopic link 6 is in same vertical direction with spacing groove 3, stop the compression to telescopic link 6, utilize extrusion spring 7's elasticity to block each other between stopper 9 and the spacing groove 3 in the same direction, be used for spacing supporting leg 4.

According to the working process, the following steps are known:

through the portable effect of supporting leg 4, not only be convenient for remove boiler body 1 more, can adapt to not through the boiler service environment of height through contracting supporting leg 4, have very high flexibility.

Further, a base 10 is arranged at the bottom of the boiler body 1, a connecting block 11 fixedly connected with the bottom of the boiler body 1 is arranged between every two of the four supporting legs 4, the four connecting blocks 11 are distributed along the bottom of the boiler body 1 in an annular array, connecting grooves 12 are arranged on the four connecting blocks 11, and the bottom of the four connecting blocks 11 are all provided with clamping rods 14 matched with the connecting grooves 12 for use, and the bottom ends of the four clamping rods 14 are all fixedly connected with the top of the base 10, wherein, the four clamping bars 14 are distributed along the top of the base 10 in an annular array, and particularly, the connecting grooves 12 in the four connecting blocks 11 at the bottom of the boiler body 1 are mutually clamped with the four clamping bars 14, so that the stability of the whole boiler body 1 is enhanced, simultaneously through the mode of mutual block, be convenient for more dismantle between boiler body 1 and base 10, also accelerated boiler body 1's installation effectiveness equally.

Further, the upper portion both sides of four kellies 14 all are connected with fixture block 15 through the rotation of torsional spring pivot, and the draw-in groove 13 that cooperation fixture block 15 used is all seted up to the inner wall both sides of spread groove 12, and is concrete, through the mutual block between fixture block 15 of kellies 14 both sides and the draw-in groove 13 in the spread groove 12, has further strengthened boiler body 1's stability.

Furthermore, the two sides of the outer wall of each of the four clamping bars 14 are fixedly connected with the top of the base 10 through the reinforcing ribs 16, and particularly, the reinforcing ribs 16 are arranged on the two sides of each clamping bar 14, so that the stability of the clamping bars 14 is further enhanced.

Further, all strengthening ribs 16's top all is connected with branch 17 through the round pin axle rotation, and the strengthening groove 18 that cooperation branch 17 used is seted up to the bottom of connecting block 11, and is concrete, through the supporting effect of branch 17 to strengthening groove 18, and then has further strengthened the steadiness between connecting block 11 and kelly 14.

Furthermore, four L-shaped sliding grooves 2 are in clearance fit with four sliding blocks 5 respectively.

In conclusion, through the mutual block of spread groove 12 and four kellies 14 in four connecting blocks 11 of boiler body 1 bottom, whole boiler body 1's steadiness has not only been strengthened, simultaneously through the mode of mutual block, be convenient for more dismantle between boiler body 1 and the base 10, boiler body 1's installation effectiveness has also been accelerated equally, through mutual block between the fixture block 15 of kellies 14 both sides and the draw-in groove 13 in the spread groove 12, boiler body 1's stability has further been strengthened, through set up strengthening rib 16 in the both sides of kellies 14, the steadiness of kellies 14 has further been strengthened.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the principles of the present invention may be applied to any other embodiment without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. A novel energy-saving low-carbon emission-reducing boiler comprises a boiler body (1) and is characterized in that L-shaped sliding grooves (2) are formed in four corners of the boiler body (1), supporting legs (4) are arranged on one sides, close to the four L-shaped sliding grooves (2), of the boiler body (1) respectively, the supporting legs (4) are connected with the L-shaped sliding grooves (2) in a sliding mode through sliding blocks (5), telescopic rods (6) are connected to outer walls of two sides of the supporting legs (4) in a rotating mode through torsion spring rotating shafts, fixed blocks (8) are fixedly connected to the upper portion and the lower portion of each telescopic rod (6), extrusion springs (7) are sleeved on the telescopic rods (6), two ends of each extrusion spring (7) are fixedly connected with the two fixed blocks (8) respectively, and limiting blocks (9) are fixedly connected to one end, far away from the supporting legs (4), of each telescopic rod (6), and the inner walls of the horizontal section and the vertical section of the L-shaped sliding groove (2) are provided with limit grooves (3) matched with the limit blocks (9) for use.

2. The novel energy-saving low-carbon emission-reducing boiler as claimed in claim 1, wherein a base (10) is arranged at the bottom of the boiler body (1), a connecting block (11) fixedly connected with the bottom of the boiler body (1) is arranged between every two of the four supporting legs (4), the four connecting blocks (11) are distributed along the bottom of the boiler body (1) in an annular array, a connecting groove (12) is formed in each of the four connecting blocks (11), clamping rods (14) matched with the connecting groove (12) in use are arranged at the bottoms of the four connecting blocks (11), the bottom ends of the four clamping rods (14) are fixedly connected with the top of the base (10), and the four clamping rods (14) are distributed along the top of the base (10) in an annular array.

3. The novel energy-saving low-carbon emission-reducing boiler as claimed in claim 2, wherein the four clamping rods (14) are rotatably connected with the clamping blocks (15) at two sides of the upper part through torsion spring rotating shafts, and the clamping grooves (13) matched with the clamping blocks (15) are formed at two sides of the inner wall of the connecting groove (12).

4. The novel energy-saving low-carbon emission-reducing boiler as claimed in claim 3, wherein two sides of the outer wall of each of the four clamping rods (14) are fixedly connected with the top of the base (10) through reinforcing ribs (16).

5. The novel energy-saving low-carbon emission-reducing boiler according to claim 4, characterized in that the tops of all the reinforcing ribs (16) are rotatably connected with supporting rods (17) through pin shafts, and the bottom of the connecting block (11) is provided with reinforcing grooves (18) matched with the supporting rods (17) for use.

6. The novel energy-saving low-carbon emission-reducing boiler according to claim 5, wherein the four L-shaped chutes (2) are in clearance fit with the four sliding blocks (5) respectively.

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