CN219607759U - Steam complementary energy replacement device - Google Patents

Abstract

The utility model discloses a residual energy replacement device for steam, which comprises a box body, and a water inlet pipe, an air inlet pipe and a side box which are arranged on the side wall of the box body, wherein the water inlet pipe and the air inlet pipe penetrate through the side wall of the box body, an exhaust pipe is arranged at the top of the box body, a drain pipe is arranged on one side of the box body far away from the water inlet pipe, the drain pipe penetrates through the side wall of the box body, the water inlet pipe is communicated with the drain pipe through a spiral pipeline, the spiral pipeline is positioned in the box body, the drain pipe is communicated with the water inlet pipe through a communicating pipeline, a filter plate is arranged at the bottom of the box body, a water flow assisting mechanism and a linkage mechanism are arranged between the water inlet pipe and the air inlet pipe, and a water flow control mechanism is arranged in the water inlet pipe.

Description

Steam complementary energy replacement device

Technical Field

The utility model relates to the technical field of residual steam energy replacement, in particular to a residual steam energy replacement device.

Background

At present, steam is also called steam, the temperature of the steam is higher, the steam is a byproduct of the operation of devices such as a boiler and the like, in daily production and life, because the content of harmful gas in the steam is lower, the steam is generally directly discharged into the atmosphere, high-temperature steam contains a large amount of heat energy, but because the high-temperature steam is difficult to preserve, only the high-temperature steam can be directly discharged into the atmosphere, the treatment mode has low energy utilization rate, the atmospheric temperature can possibly be excessively high, certain influence is caused on the environment, the steam is difficult to utilize in daily production, the cold water is heated by the steam, but the cold water and the steam cannot be accurately proportioned, and condensed water drops in the steam are not treated, so that time and labor are wasted, and the steam cannot be utilized to the maximum extent.

For this purpose, we have devised a steam complementary energy displacement device.

Disclosure of Invention

The utility model aims to solve the problem of providing a steam complementary energy replacement device which can maximally utilize steam.

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

the utility model provides a surplus energy replacement device of steam, includes the box to and set up inlet tube, intake pipe and the side case at the box lateral wall, inlet tube and intake pipe run through the box lateral wall, the box top is equipped with the blast pipe, box is kept away from inlet tube one side and is equipped with the drain pipe, the drain pipe runs through the box lateral wall, the inlet tube is linked together with the drain pipe through helical piping, helical piping is located the box, the drain pipe is linked together with the inlet tube through the communicating pipeline, the bottom half is equipped with the filter plate, be equipped with rivers assist drive mechanism and link gear between inlet tube and the intake pipe, be equipped with rivers control mechanism in the inlet tube.

Preferably, the water flow power assisting mechanism comprises a first belt pulley, a driving belt, a first bevel gear, a power assisting plate, a first driving shaft, a cross plate, a second bevel gear, a second belt pulley, a second driving shaft and a third driving shaft, wherein the cross plate is arranged in the air inlet pipe through the first driving shaft, the first driving shaft penetrates through the air inlet pipe and is fixedly connected with the first belt pulley, the second driving shaft is fixedly connected to the inner side wall of the side box, the second belt pulley is fixed on the second driving shaft, the first belt pulley is driven by the driving belt and the second belt pulley, the power assisting plate is vertically and rotatably connected to the bottom of the water inlet pipe through the third driving shaft, and the first bevel gear is meshed with the second bevel gear arranged at the bottom of the third driving shaft.

Preferably, the first hole and the first through groove are respectively formed in the top of the water inlet pipe and the top of the air inlet pipe, the transmission mechanism comprises a floating plate, a lifting rod, a connecting plate and a baffle plate, the lifting rod is sleeved in the first hole, the floating plate is fixedly connected with the lifting rod, the lifting rod is fixedly connected with the connecting plate, the baffle plate slides in the first through groove of the air inlet pipe, and the baffle plate is fixedly connected with the connecting plate.

Preferably, the water flow control mechanism comprises a loop bar, two valve baffles, two connecting rods and a loop, wherein the top and two sides of the water inlet pipe are respectively provided with a second hole and a second penetrating groove, the loop bar is sleeved in the second hole, the loop bar is sleeved with the loop bar, the two ends of the loop bar are respectively provided with a first penetrating hole, the valve baffles slide in the second penetrating grooves, the top of the valve baffles is provided with a second penetrating hole, and the two ends of the connecting rods are respectively sleeved in the first penetrating holes and the second penetrating holes of the loop bar and the valve baffles.

Preferably, the density of the floating plate is less than that of water, and the floating plate is made of hydrophobic materials.

Preferably, the first drive shaft is disposed above the intake tube axis.

The beneficial effects of the utility model are as follows:

1. according to the utility model, the water flow and the steam are linked through the linkage mechanism, so that the water flow and the steam are always balanced, insufficient water flow heating or low steam use efficiency caused by excessive water flow or excessive steam is avoided, and the utilization of the steam is dynamically controlled through the water flow control mechanism.

2. According to the utility model, when steam is flushed into the box body, the water flow booster mechanism boosts the water flow in the box body through the cross plate, so that the water flow can pass through the spiral pipeline more quickly, the water flow is repeatedly heated, the integral heating speed is improved, the steam utilization rate is improved, and the steam is discharged through the upper exhaust pipe.

Drawings

FIG. 1 is a two isometric view of a residual steam energy replacement apparatus according to the present utility model;

FIG. 2 is a front view of a residual energy steam replacement device according to the present utility model;

FIG. 3 is a schematic diagram of a device for exchanging residual energy of steam according to the present utility model;

fig. 4 is a schematic diagram of a device for exchanging residual energy of steam according to the present utility model.

In the figure: 1. a case; 2. an exhaust pipe; 3. a filter plate; 4. a water inlet pipe; 5. an air inlet pipe; 6. a drain pipe; 7. a loop bar; 8. a valve baffle; 9. a floating plate; 10. a connecting plate; 11. a baffle; 12. a first pulley; 13. a transmission belt; 14. a first bevel gear; 15. a booster plate; 16. a cross plate; 17. a first drive shaft; 18. a connecting rod; 19. a collar; 20. a helical pipe; 21. and communicating the pipeline.

Detailed Description

Referring to fig. 1-3, a residual energy replacement device for steam comprises a box body 1, and a water inlet pipe 4, an air inlet pipe 5 and a side box which are arranged on the side wall of the box body 1 and are respectively used for water inlet, steam filling and protection of pipeline parts, wherein the water inlet pipe 4 and the air inlet pipe 5 penetrate through the side wall of the box body 1 and are respectively used for water inlet and steam filling, an exhaust pipe 2 is arranged at the top of the box body 1 and is used for discharging gas with temperature reduced but not condensed water out of the box body, a drain pipe 6 is arranged on one side, away from the water inlet pipe 4, of the box body 1 and is used for discharging heated water out of the box body 1, the drain pipe 6 penetrates through the side wall of the box body 1, the water inlet pipe 4 is communicated with the drain pipe 6 through a spiral pipeline 20, so that water flows in the box body 1 through steam, the spiral pipeline 20 is positioned in the box body 1, so that the water flows in the mode of being heated through the steam when the spiral pipeline 20, the drain pipe 6 is communicated with the water inlet pipe 4 through the communication pipeline 21, the water flow can flow back to the water inlet pipe 4 again when the temperature of the steam is insufficient, the temperature of the steam is low, the water flows back to the water inlet pipe 4 for reheating, the water is arranged at the bottom of the box body 1, the water inlet pipe 3 is used for filtering the water filtering plate 4, the water filtering plate 4 is used for condensing the water, and the water filtering mechanism is convenient, the water inlet pipe 4 is arranged, and the water filtering mechanism is used for controlling the water filtering mechanism is arranged, and the water filtering mechanism is used, and the water filtering mechanism is arranged, and after the water filtering mechanism 4.

The water flow power assisting mechanism comprises a first belt pulley 12, a driving belt 13, a first bevel gear 14, a power assisting plate 15, a first driving shaft 17, a cross plate 16, a second bevel gear, a second belt pulley, a second driving shaft and a third driving shaft, wherein the cross plate 16 is arranged in the air inlet pipe 5 through the first driving shaft 17 and used for converting the impact force of air into force for enhancing the water flow speed, the first driving shaft 17 penetrates through the air inlet pipe 5 and is fixedly connected with the first belt pulley 12 and used for upwards driving the force of the cross plate 16, the second driving shaft is fixedly connected on the inner side wall of the side box and used for upwards driving the force of the cross plate 16, the second belt pulley is fixedly arranged on the second driving shaft, the first belt pulley 12 is in vertical rotation connection with the bottom of the water inlet pipe 4 through the third driving shaft and used for converting the force into force for driving the water flow, and the first bevel gear 14 is meshed with the second bevel gear arranged at the bottom of the third driving shaft and used for driving the power assisting plate 15.

The first hole and the first through groove have been seted up respectively at inlet tube 4 and intake pipe 5 top, drive mechanism includes kickboard 9, lifter, connecting plate 10 and baffle 11, the lifter cover is established in first hole, kickboard 9 is used for lifting whole mechanism when rivers lift kickboard 9 with lifter fixed connection, lifter and connecting plate 10 fixed connection, baffle 11 slides in intake pipe 5 first through groove, baffle 11 and connecting plate 10 fixed connection are used for when kickboard 9 will connecting plate 10, baffle 11 follows connecting plate 10 and lifts up together.

The water flow control mechanism comprises a loop bar 7, two valve baffle plates 8, two connecting rods 18 and a collar 19, wherein a second hole and a second through groove are respectively arranged at the top and two sides of the water inlet pipe 4, the loop bar 7 is sleeved in the second hole, so that the loop bar 7 can slide up and down in the second hole, the collar 19 is sleeved on the loop bar 7 and is used for linking the valve baffle plates 8, first through holes are respectively arranged at two ends of the collar 19, the valve baffle plates 8 slide in the second through groove and are used for controlling the water flow, second through holes are arranged at the top of the valve baffle plates 8 and are used for linking the connecting rods 18, two ends of each connecting rod 18 are respectively sleeved in the first through holes and the second through holes of the collar 19 and the valve baffle plates 8, the valve baffle plates 8 are closed when the loop bar 7 falls, and the valve baffle plates 8 shrink when the loop bar 7 is lifted, so that the water flow is controlled.

The floating plate 9 is less dense than water and is of a hydrophobic material for lifting the floating plate as water flows through the inlet pipe 4, thereby interlocking with the lower baffle 11.

A first drive shaft 17 is arranged above the axis of the air inlet pipe 5 for driving the cross plate 16 to rotate when steam passes through the air inlet pipe 5 so as to drive the booster plate 15 upwards.

The working principle of the utility model is as follows: when water flows into the spiral pipeline 20 in the box body 1 through the water inlet pipe 4, the water flows lift the floating plate 9, the baffle 11 in the air inlet pipe 5 below is lifted together, steam enters the box body 1 through the air inlet pipe 5, the cross plate 16 in the air inlet pipe 5 is driven when the steam enters the box body 1, the cross plate 16 drives the power assisting plate 15 to provide continuous thrust for the water flow through transmission, when the water flow and the steam respectively enter the spiral pipeline 20 and the box body 1, the steam continuously heats the water flow in the spiral pipeline, during the heating process, the steam drops after being condensed into water drops due to cooling, the water drops are recovered after being simply filtered through the filter plate 3 at the bottom of the box body 1, the residual steam after the heating is discharged out of the box body 1 through the air outlet pipe 2, and the heated water flow is discharged out of the box body 1 through the water outlet pipe 6, and if the heated water flow is insufficient to reach the use condition due to the excessive water flow or the insufficient steam, the water flow is guided into the water inlet pipe 4 again through the communication pipeline 21 for the water outlet pipe 6 and the water inlet pipe 4 for reheating.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides a surplus energy replacement device of steam, includes box (1) to and set up inlet tube (4), intake pipe (5) and the side case at box (1) lateral wall, its characterized in that, inlet tube (4) and intake pipe (5) run through box (1) lateral wall, box (1) top is equipped with blast pipe (2), box (1) are kept away from inlet tube (4) one side and are equipped with drain pipe (6), drain pipe (6) run through box (1) lateral wall, inlet tube (4) are linked together through helical piping (20) and drain pipe (6), helical piping (20) are located box (1), drain pipe (6) are linked together through connecting piping (21) and inlet tube (4), box (1) bottom is equipped with filter plate (3), be equipped with rivers helping hand mechanism and air intake pipe (5) between inlet tube (4), be equipped with rivers control mechanism in inlet tube (4).

2. The steam complementary energy replacement device according to claim 1, wherein the water flow power assisting mechanism comprises a first belt pulley (12), a driving belt (13), a first bevel gear (14), a power assisting plate (15), a first driving shaft (17), a cross plate (16), a second bevel gear, a second belt pulley, a second driving shaft and a third driving shaft, the cross plate (16) is arranged in the air inlet pipe (5) through the first driving shaft (17), the first driving shaft (17) penetrates through the air inlet pipe (5) and is fixedly connected with the first belt pulley (12), the second driving shaft is fixedly connected on the inner side wall of the side box, the second belt pulley is fixedly connected with the second driving shaft, the first belt pulley (12) is in driving with the second belt pulley through the driving belt (13), the power assisting plate (15) is in vertical rotation connection with the bottom of the water inlet pipe (4) through the third driving shaft, and the first bevel gear (14) is in meshed driving with the second bevel gear arranged at the bottom of the third driving shaft.

3. The device for replacing complementary energy of steam according to claim 1, wherein the top of the water inlet pipe (4) and the top of the air inlet pipe (5) are respectively provided with a first hole and a first through groove, the transmission mechanism comprises a floating plate (9), a lifting rod, a connecting plate (10) and a baffle plate (11), the lifting rod is sleeved in the first hole, the floating plate (9) is fixedly connected with the lifting rod, the lifting rod is fixedly connected with the connecting plate (10), the baffle plate (11) slides in the first through groove of the air inlet pipe (5), and the baffle plate (11) is fixedly connected with the connecting plate (10).

4. The residual steam energy replacement device according to claim 1, wherein the water flow control mechanism comprises a sleeve rod (7), two valve baffles (8), two connecting rods (18) and a sleeve ring (19), the top and two sides of the water inlet pipe (4) are respectively provided with a second hole and a second through groove, the sleeve rod (7) is sleeved in the second hole, the sleeve ring (19) is sleeved on the sleeve rod (7), the two ends of the sleeve ring (19) are respectively provided with a first through hole, the valve baffles (8) slide in the second through grooves, the top of the valve baffles (8) are respectively provided with a second through hole, and the two ends of the connecting rods (18) are respectively sleeved in the first through holes and the second through holes of the sleeve ring (19) and the valve baffles (8).

5. A complementary energy displacement device for steam according to claim 3, characterized in that the floating plate (9) has a density less than that of water and is made of a hydrophobic material.

6. A complementary energy for steam displacement device according to claim 2, characterized in that the first drive shaft (17) is arranged above the axis of the air inlet pipe (5).