CN210321346U - High-efficiency energy-saving spiral plate type heat exchanger - Google Patents

Abstract

The utility model relates to a heat exchange equipment technical field just discloses an energy-efficient spiral plate heat exchanger, the on-line screen storage device comprises a base, the top fixed mounting of base has the down tube, the quantity of down tube is two, two the equal fixed mounting in top of down tube has the organism, the bottom fixed mounting of organism has the bottom block that is located between the down tube, the bottom of bottom block and the top fixed connection of base, the inside fixed mounting of organism has the heat flow pipe. This energy-efficient spiral plate heat exchanger through setting up dog, circle axle, motion board and handle, when two handle back of the body movements of mutually, will make the motion board drive dog back of the body movements of mutually through the circle axle, and then realize the effect of sheltering from to the conveyer pipe to the velocity of flow of hot fluid in the standpipe has been changed, makes operating personnel can regulate and control according to self demand, has consequently increased this heat exchanger's practicality.

Description

High-efficiency energy-saving spiral plate type heat exchanger

Technical Field

The utility model relates to a heat energy exchange equipment technical field specifically is a high-efficient energy-conserving spiral plate heat exchanger.

Background

The spiral plate heat exchanger is formed by welding two thin metal plates on a separating baffle and rolling the two thin metal plates into a spiral shape, two spiral channels are formed in the spiral plate heat exchanger by the two thin metal plates, cover plates or end sockets are respectively welded on the top and the bottom of the spiral plate heat exchanger, and cold fluid and hot fluid respectively enter the two channels and flow in the spiral plate heat exchanger in a strict countercurrent mode during heat exchange.

At present, current spiral plate heat exchanger is at the in-process that uses, when keeping cold fluid velocity of flow certain, the hot-fluid velocity of flow is fast more, will lead to the cooling effect of hot-fluid poor, but save time, on the contrary the hot-fluid velocity of flow is slow more, will lead to the cooling effect of hot-fluid good, but the time of spending is long, and current spiral plate heat exchanger can't control the velocity of flow of hot-fluid to make operating personnel can't regulate and control according to self demand, consequently need improve it.

SUMMERY OF THE UTILITY MODEL

To prior art not enough, the utility model provides an energy-efficient spiral plate heat exchanger, possess the controllable advantage of hot-fluid flow, the in-process of having solved current spiral plate heat exchanger and using, when keeping cold fluid velocity of flow certain, the hot-fluid velocity of flow is faster, it is poor to lead to the cooling effect of hot-fluid, but save time, otherwise the hot-fluid velocity of flow is slower, it is good to lead to the cooling effect of hot-fluid, but the time of cost is long, and current spiral plate heat exchanger can't control the velocity of flow of hot-fluid, thereby make operating personnel can't carry out the problem of regulation and control according to self demand.

The utility model provides a following technical scheme: a high-efficiency energy-saving spiral plate type heat exchanger comprises a base, wherein two inclined rods are fixedly mounted at the top of the base, a machine body is fixedly mounted at the top ends of the two inclined rods, a bottom block positioned between the inclined rods is fixedly mounted at the bottom of the machine body, the bottom of the bottom block is fixedly connected with the top of the base, a hot flow pipe is fixedly mounted inside the machine body, a vertical pipe positioned above the machine body is fixedly communicated with the top end of the hot flow pipe, an adjusting box is fixedly communicated with the top end of the vertical pipe, bottom rods positioned on two sides of the vertical pipe are fixedly mounted at the bottom of the adjusting box, a conveying pipe is fixedly communicated with two sides of the top of the adjusting box, a cold flow pipe positioned between the outer surfaces of the hot flow pipe is fixedly mounted inside the machine body, and a drain pipe positioned on the right side of the machine body is fixedly communicated with the other end of the cold flow pipe, the tail end of the hot flow pipe is fixedly communicated with a discharge pipe, the other end of the discharge pipe penetrates through the machine body and extends to the outside of the machine body, the tail end of the cold flow pipe is fixedly communicated with an inlet pipe, the other end of the inlet pipe penetrates through the machine body and extends to the back face of the machine body, and long openings are formed in the two sides of the front face of the adjusting box.

Preferably, the top of the inner cavity of the adjusting box is movably connected with two stop blocks positioned between the conveying pipes, the two stop blocks are symmetrical about the center of the adjusting box, and a round shaft positioned inside the long opening is fixedly installed on the front side of each stop block.

Preferably, the other end of the circular shaft is fixedly connected with a moving plate located outside the adjusting box, the back of the moving plate is movably connected with the front of the adjusting box, and a handle is fixedly mounted on the left side of the front of the moving plate.

Preferably, the front surface of the adjusting box is fixedly provided with a transverse plate positioned below the moving plate, and bayonets positioned at two sides of the vertical pipe are arranged at the top of the transverse plate.

Preferably, the bottom fixed mounting of motion board has the perpendicular piece that is located between standpipe both sides and the conveyer pipe, the inside activity of perpendicular piece has cup jointed the telescopic link, the bottom of telescopic link runs through perpendicular piece and extends to the below of perpendicular piece and is located the inside of bayonet socket.

Preferably, the top fixed mounting of telescopic link has the motion piece, the both sides of motion piece all with the inner wall swing joint of perpendicular piece, the top fixedly connected with stiff spring of motion piece, the top of stiff spring and the bottom fixed connection of motion board.

Compared with the prior art, the utility model discloses possess following beneficial effect:

1. this energy-efficient spiral plate heat exchanger through setting up dog, circle axle, motion board and handle, when two handle back of the body movements of mutually, will make the motion board drive dog back of the body movements of mutually through the circle axle, and then realize the effect of sheltering from to the conveyer pipe to the velocity of flow of hot fluid in the standpipe has been changed, makes operating personnel can regulate and control according to self demand, has consequently increased this heat exchanger's practicality.

2. This energy-efficient spiral plate heat exchanger, through setting up rigid spring, telescopic link and bayonet socket, when the handle drives the motion board motion, the riser also can drive the telescopic link motion, because the setting of bayonet socket this moment to make the continuous concertina movement of telescopic link, and because rigid spring's elastic force effect, thereby make the telescopic link can be firm card go into to the bayonet socket in, in order to prevent that the dog from taking place unexpected motion, consequently further improvement this heat exchanger's practicality.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the front view structure of the adjusting box of the present invention;

FIG. 3 is a schematic cross-sectional structural view of the vertical block of the present invention;

fig. 4 is a schematic top view of the round shaft of the present invention;

fig. 5 is a schematic front view of the present invention;

fig. 6 is a schematic view of the back view structure of the present invention.

In the figure: 1. a base; 2. a diagonal bar; 3. a bottom block; 4. a body; 5. a hot flow tube; 6. a vertical tube; 7. an adjusting box; 8. a bottom bar; 9. a delivery pipe; 10. a cold flow pipe; 11. a drain pipe; 12. a discharge pipe; 13. an inlet pipe; 14. a long opening; 15. a stopper; 16. a circular shaft; 17. a motion plate; 18. a handle; 19. a vertical block; 20. a rigid spring; 21. a motion block; 22. a telescopic rod; 23. a transverse plate; 24. and (4) a bayonet.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only 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.

Referring to fig. 1-6, a high-efficiency energy-saving spiral plate type heat exchanger comprises a base 1, wherein two inclined rods 2 are fixedly arranged at the top of the base 1, machine bodies 4 are fixedly arranged at the top ends of the two inclined rods 2, bottom blocks 3 positioned between the inclined rods 2 are fixedly arranged at the bottom of the machine body 4, the bottom of each bottom block 3 is fixedly connected with the top of the base 1, a hot flow pipe 5 is fixedly arranged inside the machine body 4, a vertical pipe 6 positioned above the machine body 4 is fixedly communicated with the top end of the hot flow pipe 5, an adjusting box 7 is fixedly communicated with the top end of the vertical pipe 6, a transverse plate 23 positioned below a moving plate 17 is fixedly arranged on the front surface of the adjusting box 7, bayonets 24 positioned at two sides of the vertical pipe 6 are arranged at the top of the transverse plate 23, stop blocks 15 positioned between conveying pipes 9 are movably connected with the top of an inner cavity of the adjusting box 7, the two stop blocks, the front of the stopper 15 is fixedly provided with a round shaft 16 positioned inside the long opening 14, the other end of the round shaft 16 is fixedly connected with a moving plate 17 positioned outside the adjusting box 7, the back of the moving plate 17 always shields the long opening 14, thereby preventing hot fluid inside the adjusting box 7 from leaking through the long opening 14, the bottom of the moving plate 17 is fixedly provided with a vertical block 19 positioned between two sides of the vertical pipe 6 and the conveying pipe 9, the inside of the vertical block 19 is movably sleeved with a telescopic rod 22, the top of the telescopic rod 22 is fixedly provided with a moving block 21, two sides of the moving block 21 are movably connected with the inner wall of the vertical block 19, the top of the moving block 21 is fixedly connected with a rigid spring 20, the rigid spring 20 is in a compression state at the moment, thereby applying a downward elastic force to the moving block 21 and the telescopic rod 22, and further enabling the telescopic rod 22 to be firmly clamped into the bayonet 24, so as to prevent the, the top end of a rigid spring 20 is fixedly connected with the bottom of the moving plate 17, the bottom end of a telescopic rod 22 penetrates through a vertical block 19 and extends to the lower part of the vertical block 19 and is positioned in a bayonet 24, the back surface of the moving plate 17 is movably connected with the front surface of the adjusting box 7, the left side of the front surface of the moving plate 17 is fixedly provided with a handle 18, the bottom of the adjusting box 7 is fixedly provided with bottom rods 8 positioned at two sides of a vertical pipe 6, the bottom end of each bottom rod 8 is fixedly connected with the top of the machine body 4, two sides of the top of the adjusting box 7 are fixedly communicated with conveying pipes 9, the inside of the machine body 4 is fixedly provided with a cold flow pipe 10 positioned between the outer surfaces of the hot flow pipe 5, the other end of the cold flow pipe 10 is fixedly communicated with a drain pipe 11 positioned at the right side of the machine body 4, the tail end of the hot flow pipe 5 is fixedly communicated with a discharge pipe 12, the other end of the inlet pipe 13 penetrates through the machine body 4 and extends to the back of the machine body 4, and the two sides of the front surface of the adjusting box 7 are both provided with long openings 14.

During operation, hot fluid enters the adjusting box 7 through the conveying pipe 9, then enters the hot flow pipe 5 through the vertical pipe 6, and finally is discharged through the discharge pipe 12, and cold fluid enters the cold flow pipe 10 through the inlet pipe 13, and finally is discharged through the discharge pipe 11, in the process, the cold fluid absorbs heat in the hot fluid, so as to cool the hot fluid, when an operator needs to control the flow rate of the cold fluid, at the moment, the operator first holds the handles 18 with both hands, so that the two handles 18 move oppositely, the moving plate 17 drives the two stoppers 15 to move oppositely through the circular shaft 16, and further the conveying pipe 9 is shielded, so that the flow rate of the hot fluid is changed, and in the process, when the moving plate 17 moves, the telescopic rod 22 continuously extrudes the rigid spring 20 through the moving block 21, when the motion plate 17 stops moving, the bottom end of the telescopic rod 22 will be firmly clamped into the bayonet 24 due to the elastic force of the rigid spring 20.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides an energy-efficient spiral plate heat exchanger, includes base (1), its characterized in that: the top of the base (1) is fixedly provided with two inclined rods (2), the number of the inclined rods (2) is two, the top ends of the two inclined rods (2) are fixedly provided with a machine body (4), the bottom of the machine body (4) is fixedly provided with a bottom block (3) positioned between the inclined rods (2), the bottom of the bottom block (3) is fixedly connected with the top of the base (1), a hot flow pipe (5) is fixedly arranged inside the machine body (4), the top end of the hot flow pipe (5) is fixedly communicated with a vertical pipe (6) positioned above the machine body (4), the top end of the vertical pipe (6) is fixedly communicated with an adjusting box (7), the bottom of the adjusting box (7) is fixedly provided with bottom rods (8) positioned at two sides of the vertical pipe (6), the bottom end of each bottom rod (8) is fixedly connected with the top of the machine body (4), two sides of the top of the adjusting box (7) are fixedly communicated with conveying pipes (9), the inside fixed mounting of organism (4) has cold flow pipe (10) that is located between hot flow pipe (5) surface, the other end fixed intercommunication of cold flow pipe (10) has drain pipe (11) that are located organism (4) right side, the tail end fixed intercommunication of hot flow pipe (5) has discharge pipe (12), the other end of discharge pipe (12) runs through organism (4) and extends to the outside of organism (4), the tail end fixed intercommunication of cold flow pipe (10) has admission pipe (13), the other end of admission pipe (13) runs through organism (4) and extends to the back of organism (4), long mouthful (14) have all been seted up to the positive both sides of regulating box (7).

2. An energy efficient spiral plate heat exchanger as claimed in claim 1, wherein: the top swing joint of regulating box (7) inner chamber has dog (15) that are located between conveyer pipe (9), the quantity of dog (15) is two, two dog (15) are about regulating box (7) central symmetry, the front fixed mounting of dog (15) has round axle (16) that are located long mouthful (14) inside.

3. An energy efficient spiral plate heat exchanger as claimed in claim 2, wherein: the other end fixedly connected with of circle axle (16) is located outside motion plate (17) of regulating box (7), the back of motion plate (17) and the front swing joint of regulating box (7), the positive left side fixed mounting of motion plate (17) has handle (18).

4. An energy efficient spiral plate heat exchanger as claimed in claim 1, wherein: the front surface of the adjusting box (7) is fixedly provided with a transverse plate (23) positioned below the moving plate (17), and bayonets (24) positioned on two sides of the vertical pipe (6) are arranged at the top of the transverse plate (23).

5. An energy efficient spiral plate heat exchanger as claimed in claim 3, wherein: the bottom fixed mounting of motion board (17) has riser (19) that are located between standpipe (6) both sides and conveyer pipe (9), telescopic link (22) have been cup jointed in the inside activity of riser (19), the bottom of telescopic link (22) runs through riser (19) and extends to the below of riser (19) and is located the inside of bayonet socket (24).

6. An energy efficient spiral plate heat exchanger as claimed in claim 5, wherein: the top fixed mounting of telescopic link (22) has motion piece (21), the both sides of motion piece (21) all with the inner wall swing joint of perpendicular piece (19), the top fixedly connected with rigid spring (20) of motion piece (21), the top of rigid spring (20) and the bottom fixed connection of motion board (17).

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