CN204629430U - Integrated electromagnetic induction vapor generation system - Google Patents

Abstract

The utility model provides integrated electromagnetic induction vapor generation system, belongs to steam manufacturing technology field; It solve that existing steam generating device steam luminous efficiency is low, steam wastes more technical problem; The technical solution of the utility model is: integrated electromagnetic induction steam generating device, comprising steam generating unit, comprising multiple parallel connection and gas making body of heater for generating steam; Gas collection unit, is communicated with each gas making body of heater respectively and steam in gas making body of heater exports gas collection unit to concentrates; Use gas unit, comprise multiple gas equipment be communicated with gas collection unit respectively; Recovery unit, it is communicated with gas making body of heater with gas equipment respectively, and steam flow in gas making body of heater by recovery unit; The beneficial effects of the utility model are: multiple gas making body of heater manufactures steam simultaneously, adds the generating capacity of unit interval inner vapor, improves the luminous efficiency of steam, and recovery unit, by used for gas equipment vapor recovery, avoids waste.

Description

Integrated electromagnetic induction vapor generation system

Technical field

The utility model belongs to steam manufacturing technology field, relates to a kind of electromagnetic induction vapor generation system, especially a kind of integrated electromagnetic induction vapor generation system be made up of multiple tank body.

Background technology

Steam generating device is applied very extensive in current industry and commercial field, the occasions such as such as factory, heating, hotel all need the boiler plant such as steam and hot water, along with the development of this application, instead of the mode of heatings such as traditional coal-fired heating gradually with electromagnetic induction heating, its energy consumption is less, capacity usage ratio is higher, also environmental protection more simultaneously.

Existing Electromagnetic Heating steam generating device generally includes a heating tank body, control system, a water tank, the outside of heating tank body is arranged with conductive coil, control system is electrically connected with conductive coil, feed pump is provided with between water tank and heating tank body, water in water tank is pumped in heating tank body by feed pump, control system is energized to conductive coil, under eddy current effect effect, heating tank body self-heating, the water of heating tank body to its inside is heated, thus generation steam, usual heating tank body is communicated with gas equipment, steam is delivered on gas equipment uses by heating tank body, there is following problem in this traditional Electromagnetic Heating steam generating device, 1, it only has one to heat tank body, steam generating capacity is less, steam luminous efficiency is lower, 2, steam is delivered on gas equipment by heating tank body and uses, and steam is let go after using usually, cannot reclaim and reuse, cause the waste of steam, add corresponding manufacturing cost.

In sum, in order to solve the technical problem of above-mentioned adjusting device, need to design the integrated electromagnetic induction vapor generation system that a kind of steam luminous efficiency is high, can effectively prevent steam from wasting.

Utility model content

The purpose of this utility model is the problems referred to above existed for prior art, proposes the integrated electromagnetic induction vapor generation system that a kind of steam luminous efficiency is high, can effectively prevent steam from wasting.

The purpose of this utility model realizes by following technical proposal: integrated electromagnetic induction steam generating device, comprises

Steam generating unit, it comprises multiple parallel connection and gas making body of heater for generating steam;

Gas collection unit, it is communicated with each gas making body of heater respectively and steam in gas making body of heater exports gas collection unit to concentrates;

Use gas unit, it comprises multiple gas equipment be communicated with gas collection unit respectively;

Recovery unit, it is communicated with gas making body of heater with gas equipment respectively, and steam is flow in gas making body of heater by recovery unit.

In above-mentioned integrated electromagnetic induction steam generating device, described recovery unit comprises relief line, pressure maintaining valve, constant pressure valve, relief line one end is connected with gas equipment respectively, the other end is connected with gas making body of heater, described pressure maintaining valve has multiple and is arranged between each gas equipment and relief line respectively, and described constant pressure valve is arranged on relief line.

In above-mentioned integrated electromagnetic induction steam generating device, also water return pipeline is communicated with between described relief line and gas making body of heater, water return pipeline is provided with control valve and the first water-supply valve, described control valve is positioned at water return pipeline one end near feed pipe, and described first water-supply valve is between control valve and feed pipe.

In above-mentioned integrated electromagnetic induction steam generating device, described gas collection unit comprises gas collection body of heater, described gas collection body of heater is communicated with each gas equipment with each gas making body of heater respectively, and steam uses by flow in gas making body of heater in gas collection body of heater and divided to each gas equipment by gas collection body of heater.

In above-mentioned integrated electromagnetic induction steam generating device, the first intake valve is provided with between gas collection body of heater and gas making body of heater, first intake valve is communicated with each gas making body of heater with gas collection body of heater respectively, is provided with the second intake valve be communicated with corresponding gas equipment with gas collection body of heater respectively between gas collection body of heater to each gas equipment.

In above-mentioned integrated electromagnetic induction steam generating device, gas collection bottom of furnace body is provided with draining valve.

In above-mentioned integrated electromagnetic induction steam generating device, described gas making body of heater comprises gas making flue and the conductive coil of winding outside gas making flue, and described conductive coil is hollow and energy water flowing, and Gas-making Furnace Hymecromone is crossed conductive coil heating and heated the water of its inside.

In above-mentioned integrated electromagnetic induction steam generating device, described gas making flue is outside equipped with screen layer, and described conductive coil is between gas making flue and screen layer.

In above-mentioned integrated electromagnetic induction steam generating device, described gas making flue outer surface is also provided with the first heat-insulation layer, and described conductive coil to be wrapped on the first heat-insulation layer and between the first heat-insulation layer and screen layer.

In above-mentioned integrated electromagnetic induction steam generating device, this device also includes water tank, water tank is connected with each gas making body of heater respectively by feed pipe, conductive coil two ends are communicated with feed pipe, described relief line is communicated with feed pipe, feed pipe is provided with feed pump and the second water-supply valve, and described feed pump is between relief line and gas making body of heater, and described second water-supply valve is between feed pump and gas making body of heater.

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

1, this vapor generation system adopts multiple gas making body of heater to manufacture steam simultaneously, multiple gas making body of heater is communicated with a gas collection unit, steam in each gas making body of heater flows into gas collection unit and concentrates, divide to each gas equipment by gas collection unit again, multiple gas making body of heater manufactures steam simultaneously, considerably increase the generating capacity of unit interval inner vapor, improve the luminous efficiency of steam.

2, gas collection unit achieves the centralized management of steam, is divided steam to each gas equipment by gas collection unit, the while that gas collection unit can being carried out gas equipment or separately air feed, uses more flexibly, convenient.

3, by recovery unit by used for gas equipment vapor recovery, be converted into liquid water after steam chance is cold and again flowed in gas making body of heater by recovery unit, achieving recycling of used heat, effectively saved resource, avoid waste, reduce steam manufacturing cost.

Accompanying drawing explanation

Fig. 1 is the flow chart of the utility model one preferred embodiment.

Fig. 2 is the sectional view of gas making body of heater in the utility model one preferred embodiment.

In figure, 100, system controller; 200, water tank; 210, feed pipe; 211, feed pump; 212, the second water-supply valve; 300, gas making body of heater; 310, gas making flue; 311, water inlet pipe; 312, escape pipe; 320, conductive coil; 330, screen layer; 340, the first heat-insulation layer; 400, gas collection body of heater; 410, the first intake valve; 420, draining valve; 500, gas equipment; 510, the second intake valve; 600, relief line; 610, pressure maintaining valve; 620, constant pressure valve; 700, water return pipeline; 710, control valve; 720, the first water-supply valve.

Detailed description of the invention

Be below specific embodiment of the utility model and by reference to the accompanying drawings, the technical solution of the utility model is further described, but the utility model be not limited to these embodiments.

As shown in Figure 1, integrated electromagnetic induction vapor generation system, comprises system controller 100, water tank 200, steam generating unit, gas collection unit, uses gas unit, recovery unit.

Steam generation unit comprises multiple parallel connection and gas making body of heater 300 for generating steam, as shown in Figure 2, each gas making body of heater 300 comprises gas making flue 310 and conductive coil 320, empty and be loaded with water therein in gas making flue 310, gas making flue 310 is provided with water inlet pipe 311 and escape pipe 312, conductive coil 320 winding is outside at gas making flue 310, and this conductive coil 320 is hollow.

Water tank 200 is communicated with by the water inlet pipe 311 of feed pipe 210 with each gas making flue 310, feed pipe 210 is provided with feed pump 211, water in water tank 200 is pumped in each gas making flue 310 by feed pump 211, for gas making body of heater 300 provides the water manufactured needed for steam, system controller 100 external power supply is also electrically connected with conductive coil 320, energising and power-off is implemented by system controller 100 pairs of conductive coils 320, after conductive coil 320 is energized, under eddy current effect effect, gas making flue 310 self-heating also heats the water of its inside, thus generation steam, simultaneously, the two ends of conductive coil 320 are all communicated with feed pipe 210, gas making flue 310 is in heating process, water circulates in feed pipe 210 with conductive coil 320, after conductive coil 320 water flowing, the heat that water Absorbable rod conductive coil 320 externally distributes, reach reduction operating temperature, the effect of economize energy, water flow in gas making flue 310 after conductive coil 320 preheats again, reduce the consumption of heat.

Compare traditional steam generating device, manufacture steam by multiple gas making body of heater 300 in the utility model simultaneously, considerably increase the generating capacity of unit interval inner vapor, thus improve the luminous efficiency of steam.

Gas collection unit comprises a gas collection body of heater 400, each gas making flue 310 is communicated with gas collection body of heater 400 respectively, the steam of generation is delivered in gas collection body of heater 400 concentrated by escape pipe 312 by gas making flue 310, the gas equipment 500 of multiple parallel connection is comprised with gas unit, gas collection body of heater 400 is communicated with every platform gas equipment 500 respectively and is divided to deliver on every platform gas equipment 500 by the steam assembled in gas collection body of heater 400 and uses, gas collection body of heater 400 achieves the centralized management of steam, the while that gas collection body of heater 400 can carrying out gas equipment 500 or separately air feed, use more flexible, convenient, by gas collection body of heater 400 steam divided that to deliver to every platform gas equipment 500 practical, the steam temperature that every platform gas equipment 500 uses is made to be identical, make every platform gas equipment 500 can reach identical power.

In the utility model, each gas making body of heater 300 is avoided directly to be communicated with every platform gas equipment 500, prevent each gas making body of heater 300 from making the temperature of steam produce bigger difference when manufacture, conveying steam, the steam temperature causing every platform gas equipment 500 to use is different, thus affects the power of gas equipment 500.

Recovery unit comprises relief line 600, pressure maintaining valve 610, constant pressure valve 620, relief line 600 one end is communicated with each gas equipment 500 respectively, the other end is communicated with feed pipe 210, relief line 600 can bear the steam air pressure that gas equipment 500 releases, be convenient to the recovery of steam, pressure maintaining valve 610 has multiple and is arranged between each gas equipment 500 and relief line 600 respectively, constant pressure valve 620 is arranged on relief line 600, steam is released and is flow in relief line 600 after gas equipment 500 uses, by arranging the pressure maintaining valve 610 corresponding to every platform gas equipment 500, the pressure of the steam that all gas equipments 500 can be released is reduced to the acceptable scope of relief line 600, all steams dropping to normal pressure value then collect by constant pressure valve 620, the steam pressure after collecting is made to be reduced to more stable state further.

Water return pipeline 700 is also communicated with between relief line 600 and feed pipe 210, water return pipeline 700 is provided with control valve 710 and the first water-supply valve 720, described control valve 710 is positioned at the connectivity part of water return pipeline 700 relief line 600 and water return pipeline 700, described first water-supply valve 720 is between control valve 710 and feed pipe 210, control valve 710 enters the vapor volume of water return pipeline 700 for regulating, cool in water return pipeline 700 after steam enters water return pipeline 700 and change into aqueous water, by regulating the first water-supply valve 720, the discharge entering feed pipe 210 can be regulated, water in water return pipeline 700 flows in feed pipe 210, and send in each gas making flue 310 by feed pump 211, thus realize recycling of used heat, avoid steam waste, save resource, decrease production cost simultaneously.

Further, in order to realize the adjustment of gas collection body of heater 400 air inflow, the first intake valve 410 is provided with between gas collection body of heater 400 and gas making body of heater 300, first intake valve 410 is communicated with each gas making body of heater 300 with gas collection body of heater 400 respectively, by regulating the first intake valve 410, air inflow in domination set steam stove body 400 that can be real-time, avoid the air pressure in gas collection body of heater 400 too high or too low, the too high meeting of air pressure causes gas collection body of heater 400 to explode, there is certain potential safety hazard, air pressure is too low, cannot meet and carry out air feed to gas equipment 500, gas equipment 500 also just cannot normally work, simultaneously, the adjustment of air inflow is established in order to realize use gas, the second intake valve 510 be communicated with corresponding gas equipment 500 with gas collection body of heater 400 is respectively provided with between gas collection body of heater 400 to each gas equipment 500, each second intake valve 510 controls a gas equipment 500 respectively, therefore, can to every platform gas equipment 500 air feed separately, also can to all gas equipments 500 air feed simultaneously, use more flexible, convenient

Further, draining valve 420 is provided with bottom gas collection body of heater 400, when in the long-term untapped situation of native system, and the steam in gas collection body of heater 400 is not discharged completely, so long-term, too much aqueous water can be formed in gas collection body of heater 400, as discharged not in time, then can reduce the volume of gas collection body of heater 400, the vapor volume that can hold in gas collection body of heater 400 reduces, and aqueous water contacts with steam, the temperature of steam can be reduced, thus affect the thermal efficiency of steam, after draining valve 420 is set, then can in time the water remained in gas collection body of heater 400 be discharged.

As shown in Figure 2, described gas making flue 310 is outside equipped with screen layer 330, described conductive coil 320 is between gas making flue 310 and screen layer 330, the high-frequency alternating magnetic field that screen layer 330 produces in order to screening conductive coil 320, prevent conductive coil 320 from occurring responding to the phenomenon of generating heat with other objects outside, also conductive coil 320 can be avoided to contact with extraneous low temperature simultaneously, decrease the thermal losses of conductive coil 320 simultaneously.

As improvement, the first heat-insulation layer 340 is also provided with at gas making flue 310 outer surface, described conductive coil 320 to be wrapped on the first heat-insulation layer 340 and between the first heat-insulation layer 340 and screen layer 330, first heat-insulation layer 340 is coated on gas making flue 310, gas making flue 310 is incubated, avoid gas making flue 310 to heat rear heat to scatter and disappear fast, reduce energy loss, ensure the efficiency of heating surface and steam formation efficiency.

Further, feed pipe 210 is provided with the second water-supply valve 212, between feed pump 211 and gas making body of heater 300, water return pipeline 700 will be delivered in each gas making flue 310 in water tank 200 by feed pump 211, by arranging the second water-supply valve 212, the adjustment of each gas making flue 310 inflow can be realized, thus water inlet is controlled in real time, prevent the dilutional hyponatremia in gas making flue 310 or very few.

Water in water tank 200 operationally, is first pumped in each gas making flue 310 by feed pump 211 by the utility model.

The conductive coil 320 that system controller 100 opposing connection is located at outside gas making flue 310 is energized and produces eddy current effect, thus make gas making flue 310 self-heating, the water of gas making flue 310 to its inside heats and produces steam, and steam is entered in gas collection body of heater 400 by the escape pipe 312 of gas making flue 310 and concentrates.

The steam of its inside is delivered on each gas equipment 500 and uses by gas collection body of heater 400 respectively, after using, steam releases by gas equipment 500, steam in each gas equipment 500 releases rear concentrating and enters in relief line 600, by pressure maintaining valve 610 and constant pressure valve 620, the steam air pressure entered in relief line 600 is made to be down to normal barometric pressure value, by regulating control valve 710, the vapor volume entering water return pipeline 700 can be controlled, steam cools and changes into aqueous water in water return pipeline 700, aqueous water flows in feed pipe 210 by water return pipeline 700, and again pump in each gas making flue 310 by feed pump 211, realize the recycling of used heat.

Specific embodiment described herein is only to the explanation for example of the utility model spirit.The utility model person of ordinary skill in the field can make various amendment or supplements or adopt similar mode to substitute to described specific embodiment, but can't depart from spirit of the present utility model or surmount the scope that appended claims defines.

Claims (10)

1. integrated electromagnetic induction vapor generation system, is characterized in that: comprise

Steam generating unit, it comprises multiple parallel connection and gas making body of heater for generating steam;

Gas collection unit, it is communicated with each gas making body of heater respectively and steam in gas making body of heater exports gas collection unit to concentrates;

Use gas unit, it comprises multiple gas equipment be communicated with gas collection unit respectively;

Recovery unit, it is communicated with gas making body of heater with gas equipment respectively, and steam is flow in gas making body of heater by recovery unit.

2. integrated electromagnetic induction vapor generation system according to claim 1, it is characterized in that: described recovery unit comprises relief line, pressure maintaining valve, constant pressure valve, relief line one end is connected with gas equipment respectively, the other end is connected with gas making body of heater, described pressure maintaining valve has multiple and is arranged between each gas equipment and relief line respectively, and described constant pressure valve is arranged on relief line.

3. integrated electromagnetic induction vapor generation system according to claim 2, it is characterized in that: between described relief line and gas making body of heater, be also communicated with water return pipeline, water return pipeline is provided with control valve and the first water-supply valve, described control valve is positioned at the connectivity part of water return pipeline relief line and water return pipeline, and described first water-supply valve is between control valve and feed pipe.

4. the integrated electromagnetic induction vapor generation system according to claim 1 or 3, it is characterized in that: described gas collection unit comprises gas collection body of heater, described gas collection body of heater is communicated with each gas equipment with each gas making body of heater respectively, and steam uses by flow in gas making body of heater in gas collection body of heater and divided to each gas equipment by gas collection body of heater.

5. integrated electromagnetic induction vapor generation system according to claim 4, it is characterized in that: between gas collection body of heater and gas making body of heater, be provided with the first intake valve, first intake valve is communicated with each gas making body of heater with gas collection body of heater respectively, is provided with the second intake valve be communicated with corresponding gas equipment with gas collection body of heater respectively between gas collection body of heater to each gas equipment.

6. integrated electromagnetic induction vapor generation system according to claim 4, is characterized in that: gas collection bottom of furnace body is provided with draining valve.

7. integrated electromagnetic induction vapor generation system according to claim 1, it is characterized in that: described gas making body of heater comprises gas making flue and the conductive coil of winding outside gas making flue, described conductive coil is hollow and energy water flowing, and Gas-making Furnace Hymecromone is crossed conductive coil heating and heated the water of its inside.

8. integrated electromagnetic induction vapor generation system according to claim 7, is characterized in that: described gas making flue is outside equipped with screen layer, and described conductive coil is between gas making flue and screen layer.

9. integrated electromagnetic according to claim 8 induction vapor generation system, is characterized in that: described gas making flue outer surface is also provided with the first heat-insulation layer, and described conductive coil to be wrapped on the first heat-insulation layer and between the first heat-insulation layer and screen layer.

10. the integrated electromagnetic induction vapor generation system according to claim 7 or 8 or 9, it is characterized in that: this device also includes water tank, water tank is connected with each gas making body of heater respectively by feed pipe, conductive coil two ends are communicated with feed pipe, described reclaim line is communicated with feed pipe, feed pipe is provided with feed pump and the second water-supply valve, and described feed pump is between reclaim line and gas making body of heater, and described second water-supply valve is between feed pump and gas making body of heater.