CN114671544A

CN114671544A - Novel condensate water regeneration device

Info

Publication number: CN114671544A
Application number: CN202210304221.2A
Authority: CN
Inventors: 王杰; 冯伟; 徐莲莲; 何伟; 陈嘉俊
Original assignee: Jiangsu Longjing Kejie Environmental Protection Technology Co ltd
Current assignee: Jiangsu Longjing Kejie Environmental Protection Technology Co ltd
Priority date: 2022-03-25
Filing date: 2022-03-25
Publication date: 2022-06-28
Anticipated expiration: 2042-03-25
Also published as: CN114671544B

Abstract

The invention provides a novel condensate water regeneration device which comprises a collection assembly, a filtering assembly, a softening assembly and a heat insulation assembly, wherein the collection assembly, the filtering assembly, the softening assembly and the heat insulation assembly are sequentially communicated from left to right, and the output end of the heat insulation assembly is communicated with the input end of a boiler. According to the invention, the condensed water generated in a workshop can be collected through the collecting component, then the condensed water is transmitted to the filtering component, impurities in the condensed water are filtered by the filtering component, then the filtered condensed water is softened by the softening component, the hardness of the condensed water is reduced and then the condensed water is transmitted into the heat-insulating component, the heat-insulating component can slow down the cooling speed of the condensed water, the condensed water containing heat energy in the heat-insulating component is directly supplied to a steam boiler for use, the heat energy of the condensed water is fully utilized, the consumption of fuel natural gas of the boiler is reduced, water resources and heat energy are saved, and an energy-saving effect is achieved.

Description

Novel condensate water regeneration device

Technical Field

The invention relates to the technical field of condensate water recovery, in particular to a novel condensate water regeneration device.

Background

The condensed water is liquid water formed by vapor through a condensation process, a large amount of condensed water can be produced in the workshop production process, the condensed water produced in the workshop is high-quality water and contains a large amount of heat energy, but the hardness of the condensed water exceeds the standard, and the condensed water contains other impurities, so that the condensed water produced in the workshop production process can not be directly used by a steam boiler in the workshop, the produced condensed water is generally directly discharged in the current production process, the water resource is wasted, and a large amount of valuable heat energy is wasted.

Disclosure of Invention

The invention provides a novel condensate water regeneration device, which is used for solving the technical problems that at present, as the hardness of condensate water exceeds the standard and the condensate water contains other impurities, a steam boiler in a workshop cannot directly use the condensate water produced in the production process of the workshop, the produced condensate water is generally directly discharged in the production process, and not only water resources but also a large amount of valuable heat energy is wasted.

In order to solve the above technical problems, the present invention discloses a novel condensate water regeneration device, comprising: collect subassembly, filtering component, soften subassembly and heat preservation subassembly, collect the subassembly filtering component soften the subassembly and heat preservation subassembly turns right from a left side and communicates the setting in proper order, heat preservation subassembly output and boiler input intercommunication.

Preferably, the collection assembly comprises:

the system comprises a water collecting tank, a water outlet pipe, a water inlet pipe, a water outlet pipe, a water inlet pipe, a water outlet pipe and a water outlet pipe, wherein the water collecting tank is used for collecting condensed water in a workshop;

the first electronic liquid level controller is arranged on the side wall of the collecting water tank and is used for detecting the actual liquid level of the condensed water in the collecting water tank;

the first outlet pipe, first outlet pipe sets up the collection water tank right side is close to the lower extreme position, set up first ball valve on the first outlet pipe, first outlet pipe one end with the inside intercommunication of collection water tank, the first outlet pipe other end and first force (forcing) pump input intercommunication, first force (forcing) pump with first electron liquid level controller electric connection.

Preferably, the filter assembly comprises:

the precision filter is arranged on the right side of the water collecting tank, a precision filter bag is arranged in the precision filter, a first pressure gauge is arranged at the upper end of the precision filter, a first filtering water pipe is arranged on the left side of the precision filter, a second ball valve is arranged on the first filtering water pipe, one end of the first filtering water pipe is communicated with the output end of the first pressure pump, the other end of the first filtering water pipe is communicated with the inside of the precision filter, a second drain pipe is arranged on the right side of the precision filter, and a second drain valve is arranged at the second drain pipe;

the RO reverse osmosis filter is arranged on the right side of the precision filter, the input end of the RO reverse osmosis filter is communicated with the precision filter through a second filtering water pipe, the output end of the RO reverse osmosis filter is provided with a third filtering water pipe, and one end of the third filtering water pipe is communicated with the output end of the RO reverse osmosis filter.

Preferably, the RO reverse osmosis filters are provided with a plurality of RO reverse osmosis filters, and the plurality of RO reverse osmosis filters are sequentially communicated with one another.

Preferably, the softening assembly comprises:

the system comprises at least two groups of high-temperature-resistant resin filters, wherein the two groups of high-temperature-resistant resin filters are sequentially communicated, a high-temperature-resistant resin layer is arranged in each high-temperature-resistant resin filter, a full-automatic softening valve is arranged at the upper end of each high-temperature-resistant resin filter, the input end of the full-automatic softening valve positioned on the left side is communicated with one end, away from the RO reverse osmosis filter, of a third filtering water pipe, the output end of the full-automatic softening valve positioned on the left side is communicated with the input end of the full-automatic softening valve positioned on the right side, the output end of the full-automatic softening valve positioned on the right side is provided with a first softening water pipe, one end of the first softening water pipe is communicated with the output end of the full-automatic softening valve positioned on the right side, and the input ends of the full-automatic softening valves are provided with a water inlet valve and a second pressure gauge;

the salt box is arranged outside the high-temperature-resistant resin filter, salt liquid is arranged in the salt box, a first overflow port is formed in the side wall of the upper end of the salt box, the salt box is communicated with the upper end of the high-temperature-resistant resin filter through a second softened water pipe, and a salt suction valve is arranged on the second softened water pipe;

and one end of the third softening water pipe is communicated with the upper end of the high-temperature-resistant resin filter, the other end of the third softening water pipe is communicated with the outside of the high-temperature-resistant resin filter, and an upper discharge valve is arranged on the third softening water pipe.

Preferably, the heat-insulating assembly includes:

the heat preservation hot water tank is arranged on the right side of the high-temperature-resistant resin filter, a heat preservation layer is arranged on the inner wall of the heat preservation hot water tank, a first heat preservation water pipe is arranged on the upper position of the left side wall of the heat preservation hot water tank, one end of the first heat preservation water pipe is communicated with one end, far away from the full-automatic softening valve, of the first softening water pipe, the other end of the first heat preservation water pipe extends into the heat preservation hot water tank and is provided with a first ball float valve, a sampling valve is arranged on the first heat preservation water pipe, a third drain pipe is arranged on the heat preservation hot water tank, close to the side wall of the lower end, of the heat preservation hot water tank, a third drain valve is arranged at the position of the third drain pipe, and a second overflow port is arranged on the right side wall of the heat preservation hot water tank, close to the upper end;

the second electronic liquid level controller is arranged on the side wall of the heat-preservation hot water tank and is used for detecting the actual liquid level of condensed water in the heat-preservation hot water tank;

one end of the second heat-preservation water pipe is fixedly connected with the side wall, close to the lower end, of the heat-preservation hot water tank, one end of the second heat-preservation water pipe is communicated with the interior of the heat-preservation hot water tank, the other end of the second heat-preservation water pipe is communicated with the input end of the water pump, the output end of the water pump is provided with a third heat-preservation water pipe, one end of the third heat-preservation water pipe is communicated with the output end of the water pump, and the other end of the third heat-preservation water pipe is communicated with the input end of the boiler;

the third ball valve is arranged on the second heat-preservation water pipe;

and the fourth ball valve is arranged on the third heat-preservation water pipe.

Preferably, a first stirring machine is arranged on the heat-preservation hot water tank, a first stirring shaft is arranged at the output end of the first stirring machine, and one end of the first stirring shaft extends into the heat-preservation hot water tank and is provided with a plurality of first stirring blades.

Preferably, also include the medicine adding subassembly, the medicine adding subassembly includes:

a second water inlet pipe is arranged on the left side wall of the dosing tank close to the upper end, and the output end of the second water inlet pipe extends into the dosing tank and is provided with a second ball float valve;

the dosing port is arranged at the upper end of the dosing box and communicated with the upper end of the dosing box;

one end of the first dosing pipe extends to a position close to the bottom wall inside the dosing box and is communicated with the inside of the dosing box, the other end of the first dosing pipe penetrates through the top wall of the dosing box, extends to the outside of the dosing box and is communicated with the input end of the diaphragm metering pump, and a fifth ball valve is arranged on the first dosing pipe;

one end of the second dosing pipe is communicated with the output end of the diaphragm metering pump, the other end of the second dosing pipe penetrates through the top wall of the heat-preservation hot water tank, extends into the heat-preservation hot water tank and is communicated with the interior of the heat-preservation hot water tank, and a sixth ball valve is arranged on the second dosing pipe;

the output end of the alternating current contactor is electrically connected with the input end of the diaphragm metering pump, the input end of the alternating current contactor is electrically connected with the output end of the pH detector, the input end of the pH detector is provided with a pH electrode, the pH electrode is positioned inside the heat-preservation hot water tank, and the output end of the pH electrode is electrically connected with the input end of the pH detector.

Preferably, a second stirrer is arranged on the dosing tank, a second stirring shaft is arranged at the output end of the second stirrer, and one end of the second stirring shaft extends into the dosing tank and is provided with a plurality of second stirring blades.

Preferably, the collection water tank sets up to cylindric, be provided with automatic cleaning mechanism in the collection water tank, automatic cleaning mechanism includes:

the first rotating shaft is arranged at the right lower part of the water inlet, the front end and the rear end of the first rotating shaft are respectively and rotatably connected with the inner walls of the front side and the rear side of the water collecting tank, a turbine and a first gear are sequentially arranged on the first rotating shaft from back to front, the first gear is an incomplete gear, and a left blade of the turbine is positioned under the water inlet;

the second rotating shaft is arranged on the right of the first rotating shaft, the second rotating shaft is parallel to the first rotating shaft, the rear end of the second rotating shaft is rotatably connected with the inner wall of the rear side of the collecting water tank, a second gear and a first bevel gear are sequentially arranged on the second rotating shaft from back to front, and the second gear is intermittently meshed with the first gear;

the winding drum is arranged in front of the second rotating shaft, the upper end and the lower end of the winding drum are respectively in rotating connection with the inner walls of the upper side and the lower side of the water collecting tank, the winding drum is provided with a second bevel gear, and the second bevel gear is meshed with the first bevel gear;

the two sleeves are symmetrically arranged on the outer walls of the front side and the rear side of the first drainage pipe, one end of each sleeve is hinged with the outer wall of the first drainage pipe, the other end of each sleeve is provided with a sliding column, and one end of each sliding column is connected with the inner wall of each sleeve in a sliding manner;

the first spring is arranged in the sleeve, one end of the first spring is fixedly connected with one end, close to the first drainage pipe, of the sleeve, and the other end of the first spring is fixedly connected with one end, located in the sleeve, of the sliding column;

the first scraping blade is arranged at one end, far away from the first drainage pipe, of the sliding column, and the side wall of the first scraping blade is in contact with the side wall of the collection water tank;

the second spring is arranged on the outer wall of the right side of the sleeve, one end of the second spring is fixedly connected with the inner wall of the right side of the water collecting tank, and the other end of the second spring is fixedly connected with the outer wall of the right side of the sleeve;

one end of the first steel wire rope is fixedly connected with the outer wall of the left side of the sleeve, the other end of the first steel wire rope is fixedly connected with the outer wall of the winding drum, and the first steel wire rope is wound on the outer wall of the winding drum;

the fixed rod is arranged in the first drainage pipe, the front end and the rear end of the fixed rod are respectively fixedly connected with the inner walls of the front side and the rear side of the first drainage pipe, a first sliding hole is formed in the center of the fixed rod and penetrates through the left surface and the right surface of the fixed rod, a sliding rod is connected in the first sliding hole in a sliding mode, one end of the sliding rod extends to the lower portion of the fixed rod and is fixedly connected with one end of a second steel wire rope, the other end of the second steel wire rope is fixedly connected with the outer wall of the winding drum, the second steel wire rope is wound on the outer wall of the winding drum, and one end, far away from the second steel wire rope, of the sliding rod extends to the right side of the fixed rod and is provided with a limiting plate;

the center of the sliding block is provided with a second sliding hole, the sliding block is sleeved on the sliding rod through the second sliding hole and is in sliding connection with the sliding rod, the front side wall and the rear side wall of the sliding block are both obliquely provided with second scraping blades, the second scraping blades are hinged with the side wall of the sliding block near the center, the right side of the sliding block is provided with a third spring, one end of the third spring is fixedly connected with the right side of the sliding block, and the other end of the third spring is fixedly connected with the left side wall of the limiting plate;

the fourth spring is arranged between the sliding block and the fixed rod, one end of the fourth spring is fixedly connected with the left side wall of the sliding block, and the other end of the fourth spring is fixedly connected with the right side wall of the fixed rod.

The technical scheme of the invention has the following advantages: the invention provides a novel condensate water regeneration device which comprises a collection assembly, a filtering assembly, a softening assembly and a heat insulation assembly, wherein the collection assembly, the filtering assembly, the softening assembly and the heat insulation assembly are sequentially communicated from left to right, and the output end of the heat insulation assembly is communicated with the input end of a boiler. According to the invention, the condensed water generated in a workshop can be collected through the collecting component, then the condensed water is transmitted to the filtering component, impurities in the condensed water are filtered by the filtering component, then the filtered condensed water is softened by the softening component, the hardness of the condensed water is reduced and then the condensed water is transmitted into the heat-insulating component, the heat-insulating component can slow down the cooling speed of the condensed water, the condensed water containing heat energy in the heat-insulating component is directly supplied to a steam boiler for use, the heat energy of the condensed water is fully utilized, the consumption of fuel natural gas of the boiler is reduced, water resources and heat energy are saved, and an energy-saving effect is achieved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the apparatus particularly pointed out in the written description and drawings thereof.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of the overall structure of a novel condensate water regeneration device according to the present invention;

FIG. 2 is a schematic view of a collection assembly of the present invention;

FIG. 3 is a schematic view of a filter assembly according to the present invention;

FIG. 4 is a schematic view of a softening assembly of the present invention;

FIG. 5 is a schematic view of the heat preservation assembly and the dosing assembly of the present invention;

FIG. 6 is a schematic view of a partial structure of the automatic cleaning mechanism of the present invention;

FIG. 7 is a top view of a portion of the automatic purge mechanism of the present invention;

FIG. 8 is an enlarged view taken at A of FIG. 7 in accordance with the present invention;

FIG. 9 is an enlarged view taken at B of FIG. 7 in accordance with the present invention;

FIG. 10 is a schematic view of a cleaning assembly of the present invention.

In the figure: 1. a collection assembly; 2. a filter assembly; 3. a softening component; 4. a heat preservation assembly; 5. a boiler; 6. collecting a water tank; 7. a water inlet; 8. a first drain pipe; 9. a first drain valve; 10. a first electronic liquid level controller; 11. a first water outlet pipe; 12. a first ball valve; 13. a first pressure pump; 14. a precision filter; 15. a precision filter bag; 16. a first pressure gauge; 17. a first filtered water pipe; 18. a second ball valve; 19. a second drain pipe; 20. a second drain valve; 21. an RO reverse osmosis filter; 22. a second water filtering pipe; 23. a third filtered water pipe; 24. a high temperature resistant resin filter; 25. a fully automatic softening valve; 26. a first softened water pipe; 27. a water inlet valve; 28. a second pressure gauge; 29. a salt box; 30. a first overflow port; 31. a second softened water pipe; 32. a third softening water pipe; 33. a heat preservation hot water tank; 34. a first heat-preserving water pipe; 35. a first float valve; 36. a sampling valve; 37. a third drain pipe; 38. a third drain valve; 39. a second overflow port; 40. a second electronic liquid level controller; 41. a second heat-preservation water pipe; 42. a water pump; 43. a third heat-preservation water pipe; 44. a third ball valve; 45. a fourth ball valve; 46. a first stirrer; 47. a first stirring shaft; 48. a first stirring blade; 49. a dosing box; 50. a second water inlet pipe; 51. a second float valve; 52. a medicine adding port; 53. a first dosing tube; 54. a diaphragm metering pump; 55. a fifth ball valve; 56. a second dosing tube; 57. a sixth ball valve; 58. an AC contactor; 59. a pH detector; 60. a pH electrode; 61. a second mixer; 62. a second stirring shaft; 63. a second stirring blade; 65. a first rotating shaft; 66. a turbine; 67. a first gear; 68. a second rotating shaft; 69. a second gear; 70. a first bevel gear; 71. a reel; 72. a second bevel gear; 73. a sleeve; 74. a sliding post; 75. a first spring; 76. a first blade; 77. a second spring; 78. a first wire rope; 79. fixing the rod; 80. a first slide hole; 81. a slide bar; 82. a second wire rope; 83. a limiting plate; 84. a slider; 85. a second slide hole; 86. a second wiper blade; 87. a third spring; 88. a fourth spring; 89. a dust screen; 90. a motor; 91. a screw; 92. a sliding table; 93. mounting a plate; 94. a slide bar; 95. and (3) brush hairs.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

In addition, the descriptions related to the first, the second, etc. in the present invention are only used for description purposes, do not particularly refer to an order or sequence, and do not limit the present invention, but only distinguish components or operations described in the same technical terms, and are not understood to indicate or imply relative importance or implicitly indicate the number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions and technical features between various embodiments can be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not be within the protection scope of the present invention.

Example 1:

an embodiment of the present invention provides a novel condensate water regenerating device, as shown in fig. 1 to 6, including: collect subassembly 1, filtering component 2, soften subassembly 3 and heat preservation subassembly 4, collect subassembly 1 filtering component 2 soften subassembly 3 and heat preservation subassembly 4 sets up from turning right from a left side to communicate in proper order, heat preservation subassembly 4 output and 5 input intercommunications of boiler.

The working principle and the beneficial effects of the technical scheme are as follows: the invention provides a novel condensate water regeneration device, which can recover, filter, soften and preserve heat of condensate water produced in a workshop, is convenient for a boiler 5 to be directly utilized, reduces the heating time of the boiler 5, thereby reducing the energy loss, and comprises a collection component 1, a filter component 2, a softening component 3 and a heat preservation component 4, wherein the condensate water produced in the workshop can be collected through the collection component 1, then the condensate water is transmitted to the filter component 2, impurities in the condensate water are filtered through the filter component 2, then the filtered condensate water is softened through the softening component 3, the hardness of the condensate water is reduced and then transmitted to the heat preservation component 4, the heat preservation component 4 can slow down the cooling speed of the condensate water, the condensate water containing heat energy in the heat preservation component 4 is directly supplied to the steam boiler 5 for use, and the heat energy of the condensate water is fully utilized, the consumption of fuel natural gas of the boiler 5 is reduced, water resources and heat energy are saved, and the energy-saving effect is achieved.

Example 2

On the basis of the above embodiment 1, as shown in fig. 1 to 5, the collecting assembly 1 includes:

the water collecting tank 6 is used for collecting condensed water in a workshop, a water inlet 7 and a first drainage pipe 8 are arranged on the side wall of the water collecting tank 6, and a first drainage valve 9 is arranged at the first drainage pipe 8;

the first electronic liquid level controller 10 is arranged on the side wall of the water collection tank 6, and the first electronic liquid level controller 10 is used for detecting the actual liquid level of the condensed water in the water collection tank 6;

the first water outlet pipe 11 is arranged at the position, close to the lower end, of the right side of the water collection tank 6, a first ball valve 12 is arranged on the first water outlet pipe 11, one end of the first water outlet pipe 11 is communicated with the interior of the water collection tank 6, the other end of the first water outlet pipe 11 is communicated with the input end of a first pressure pump 13, and the first pressure pump 13 is electrically connected with the first electronic liquid level controller 10;

the filter assembly 2 includes:

the precision filter 14 is arranged on the right side of the collecting water tank 6, a precision filter bag 15 is arranged inside the precision filter 14, a first pressure gauge 16 is arranged at the upper end of the precision filter 14, a first water filtering pipe 17 is arranged on the left side of the precision filter 14, a second ball valve 18 is arranged on the first water filtering pipe 17, one end of the first water filtering pipe 17 is communicated with the output end of the first pressure pump 13, the other end of the first water filtering pipe 17 is communicated with the inside of the precision filter 14, a second water discharging pipe 19 is arranged on the right side of the precision filter 14, and a second water discharging valve 20 is arranged at the second water discharging pipe 19;

an RO reverse osmosis filter 21, wherein the RO reverse osmosis filter 21 is arranged at the right side of the precision filter 14, the input end of the RO reverse osmosis filter 21 is communicated with the precision filter 14 through a second filtered water pipe 22, the output end of the RO reverse osmosis filter 21 is provided with a third filtered water pipe 23, and one end of the third filtered water pipe 23 is communicated with the output end of the RO reverse osmosis filter 21;

the number of the RO reverse osmosis filters 21 is multiple, and the plurality of RO reverse osmosis filters 21 are sequentially communicated;

the softening assembly 3 comprises:

the high-temperature resistant resin filter 24, the high-temperature resistant resin filter 24 is at least provided with two groups, the two groups of the high-temperature resistant resin filters 24 are sequentially communicated, a high-temperature-resistant resin layer is arranged in the high-temperature-resistant resin filter 24, a full-automatic softening valve 25 is arranged at the upper end of the high-temperature-resistant resin filter 24, the input end of the full-automatic softening valve 25 positioned at the left side is communicated with one end of the third water filtering pipe 23 far away from the RO reverse osmosis filter 21, the output end of the full-automatic softening valve 25 positioned at the left side is communicated with the input end of the full-automatic softening valve 25 positioned at the right side, a first softening water pipe 26 is arranged at the output end of the full-automatic softening valve 25 positioned at the right side, one end of the first softening water pipe 26 is communicated with the output end of the fully automatic softening valve 25 on the right side, the input ends of the full-automatic softening valves 25 are provided with a water inlet valve 27 and a second pressure gauge 28;

the salt tank 29 is arranged outside the high-temperature-resistant resin filter 24, salt liquid is arranged in the salt tank 29, a first overflow port 30 is formed in the side wall of the upper end of the salt tank 29, the salt tank 29 is communicated with the upper end of the high-temperature-resistant resin filter 24 through a second softened water pipe 31, and a salt absorption valve is arranged on the second softened water pipe 31;

one end of the third softening water pipe 32 is communicated with the upper end of the high-temperature-resistant resin filter 24, the other end of the third softening water pipe 32 is communicated with the outside of the high-temperature-resistant resin filter 24, and an upper discharge valve is arranged on the third softening water pipe 32;

the heat preservation assembly 4 includes:

the heat preservation hot water tank 33 is arranged on the right side of the high-temperature-resistant resin filter 24, a heat preservation layer is arranged on the inner wall of the heat preservation hot water tank 33, a first heat preservation water pipe 34 is arranged on the upper portion of the left side wall of the heat preservation hot water tank 33, one end of the first heat preservation water pipe 34 is communicated with one end, far away from the full-automatic softening valve 25, of the first softening water pipe 26, the other end of the first heat preservation water pipe 34 extends into the heat preservation hot water tank 33 and is provided with a first ball float valve 35, a sampling valve 36 is arranged on the first heat preservation water pipe 34, a third drain pipe 37 is arranged on the heat preservation hot water tank 33 close to the lower end side wall, a third drain valve 38 is arranged on the third drain pipe 37, and a second overflow port 39 is arranged on the right side wall of the heat preservation hot water tank 33 close to the upper end;

the second electronic liquid level controller 40 is arranged on the side wall of the heat-preservation hot water tank 33, and the second electronic liquid level controller 40 is used for detecting the actual liquid level of condensed water in the heat-preservation hot water tank 33;

one end of the second heat-preservation water pipe 41 is fixedly connected with the side wall, close to the lower end, of the heat-preservation hot water tank 33, one end of the second heat-preservation water pipe 41 is communicated with the inside of the heat-preservation hot water tank 33, the other end of the second heat-preservation water pipe 41 is communicated with the input end of a water pump 42, the output end of the water pump 42 is provided with a third heat-preservation water pipe 43, one end of the third heat-preservation water pipe 43 is communicated with the output end of the water pump 42, and the other end of the third heat-preservation water pipe 43 is communicated with the input end of the boiler 5;

a third ball valve 44, wherein the third ball valve 44 is arranged on the second heat-preservation water pipe 41;

a fourth ball valve 45, wherein the fourth ball valve 45 is arranged on the third heat-preservation water pipe 43;

a first stirring machine 46 is arranged on the heat-preservation hot water tank 33, a first stirring shaft 47 is arranged at the output end of the first stirring machine 46, one end of the first stirring shaft 47 extends into the heat-preservation hot water tank 33, and a plurality of first stirring blades 48 are arranged;

still include the medicine subassembly that adds, it includes to add the medicine subassembly:

a dosing box 49, wherein a second water inlet pipe 50 is arranged on the left side wall of the dosing box 49 close to the upper end position, and the output end of the second water inlet pipe 50 extends into the dosing box 49 and is provided with a second ball float valve 51;

a dosing port 52, wherein the dosing port 52 is arranged at the upper end of the dosing box 49, and the dosing port 52 is communicated with the upper end of the dosing box 49;

a first dosing pipe 53, one end of the first dosing pipe 53 extends to a position close to the bottom wall inside the dosing box 49 and is communicated with the inside of the dosing box 49, the other end of the first dosing pipe 53 penetrates through the top wall of the dosing box 49, extends to the outside of the dosing box 49 and is communicated with the input end of a diaphragm metering pump 54, and a fifth ball valve 55 is arranged on the first dosing pipe 53;

one end of the second dosing pipe 56 is communicated with the output end of the diaphragm metering pump 54, the other end of the second dosing pipe 56 penetrates through the top wall of the heat-preservation hot water tank 33, extends into the heat-preservation hot water tank 33 and is communicated with the interior of the heat-preservation hot water tank 33, and a sixth ball valve 57 is arranged on the second dosing pipe 56;

the output end of the alternating current contactor 58 is electrically connected with the input end of the diaphragm metering pump 54, the input end of the alternating current contactor 58 is electrically connected with the output end of the pH detector 59, the input end of the pH detector 59 is provided with a pH electrode 60, the pH electrode 60 is positioned inside the heat-preservation hot water tank 33, and the output end of the pH electrode 60 is electrically connected with the input end of the pH detector 59;

the feeding box 49 is provided with a second stirrer 61, the output end of the second stirrer 61 is provided with a second stirring shaft 62, and one end of the second stirring shaft 62 extends into the feeding box 49 and is provided with a plurality of second stirring blades 63.

The working principle and the beneficial effects of the technical scheme are as follows: the method comprises the steps that all condensed water produced in a workshop is discharged into a collecting water tank 6, a first water discharge pipe 8 is arranged on the side wall of the collecting water tank 6, a first water discharge valve 9 is arranged at the position of the first water discharge pipe 8, when the condensed water in the collecting water tank 6 needs to be discharged, the first water discharge valve 9 can be opened to discharge the condensed water, a first electronic liquid level controller 10 with signal output is arranged in the collecting water tank 6, the first electronic liquid level controller 10 can detect the liquid level of the condensed water in the collecting water tank 6, when the condensed water in the collecting water tank 6 is at a preset first high water level, a first pressure pump 13 is started to output the condensed water into a precision filter 14, fine particles in the condensed water are filtered through a precision filter bag 15 in the precision filter 14, a first pressure gauge 16 is arranged on the precision filter 14, the pressure in the precision filter 14 can be monitored in real time through the first pressure gauge 16, and a second water discharge pipe 19 is arranged at a position, which is close to the lower end, of the precision filter 14, the second drain pipe 19 is provided with a second drain valve 20, the condensed water in the precision filter 14 can be discharged by opening the second drain valve 20, the condensed water filtered by the precision filter 14 can flow into the RO reverse osmosis filter 21 through a second water filtering pipe 22, the RO reverse osmosis filter 21 filters dissolved salts, colloids, microorganisms, organic matters and the like in the condensed water, secondary filtration of the condensed water is realized, then the condensed water is conveyed to the left full-automatic softening valve 25 from a third water filtering pipe 23 arranged at the output end of the right RO reverse osmosis filter 21, then the condensed water flows into the high-temperature resistant resin filter 24 through the full-automatic softening valve 25, a high-temperature resistant resin layer is arranged in the high-temperature resistant resin filter 24, the condensed water can soften the high-temperature condensed water through the high-temperature resistant resin filter 24, and then the softened condensed water flows into the full-automatic softening valve 25, the condensate water can pass through the high-temperature resistant resin layer from top to bottom, calcium and magnesium ions in the condensate water perform a displacement reaction with polymeric resin in the high-temperature resistant resin layer to adsorb the calcium and magnesium ions, so that the hardness of the water is reduced, the hardness of the outlet water is ensured to be less than 0.3mmlo/L, the water inlet requirement of the boiler 5 is met, when the water yield reaches a preset flow, the softening component 3 is automatically switched to another set of high-temperature resistant resin filter 24, the unused high-temperature resistant resin layer in the high-temperature resistant resin filter 24 performs automatic regeneration, the saline solution in the salt tank 29 is automatically sucked into an exchange column central tube arranged in the high-temperature resistant resin filter 24 through the salt suction valve during regeneration, entering the bottom of the exchange column, performing countercurrent cleaning and regeneration from bottom to top, discharging regenerated cleaning liquid into a trench through an upper discharge valve, automatically opening a water inlet valve 27 to perform automatic backwashing on a renewable high-temperature-resistant resin layer after salt feeding is completed, reaching a set time, completing backwashing, enabling the equipment to enter a standby state, enabling softened condensate water to be stored into a heat-preservation hot water tank 33 through a first heat-preservation water pipe 34, arranging a heat-preservation layer on the inner wall of the heat-preservation hot water tank 33 to reduce heat loss of the condensate water, arranging a sampling valve 36 on the first heat-preservation water pipe 34 to facilitate sampling detection of the softened condensate water, arranging a second electronic liquid level controller 40 in the heat-preservation hot water tank 33, enabling the actual liquid level of the condensate water in the heat-preservation hot water tank 33 to be detected through the second electronic liquid level controller 40, arranging a second overflow port 39 on the side wall of the upper end of the heat-preservation hot water tank 33 to enable the volume of the condensate water in the heat-preservation hot water tank 33 to be controlled, by arranging the third drain pipe 37, the condensed water in the heat preservation hot water tank 33 can be drained after the third drain valve 38 is opened, the condensed water in the heat preservation hot water tank 33 is convenient to control, when the boiler 5 needs water, a signal is output to the water pump 42 of the heat preservation hot water tank 33, the water pump 42 can provide high-temperature condensed water for the boiler 5 after being started, the heating time of the boiler 5 is shortened, and the energy consumption is reduced;

the workshop condensed water flows back to the condensed water tank through a pipeline, but the pH value of the condensed water is low, so that a dosing assembly is arranged, alkali is added into the heat preservation hot water tank 33 through the dosing assembly to adjust the pH value of the condensed water in the heat preservation hot water tank 33, so as to ensure the safe operation of subsequent equipment, the dosing assembly is arranged, the second water inlet pipe 50 is firstly opened to add water into the dosing tank 49, an alkaline medicament is added into the dosing tank 49 through the dosing port 52 for mixing, the alkaline medicament can be sodium hydroxide, then the mixed alkaline liquid is conveyed into the heat preservation hot water tank 33 through the diaphragm metering pump 54, the adding amount of the alkaline liquid is controlled by the pH detector 59, the pH value of the condensed water in the heat preservation hot water tank 33 is adjusted to be within the preset range of 7-8, the pH electrode 60 can detect the pH value of the condensed water in the heat preservation tank 33, and directly feeds the pH value back to the pH detector 59, and a signal is transmitted to the diaphragm metering pump 54 through the alternating current contactor 58 by the pH detector 59, so that the opening and closing of the diaphragm metering pump 54 are controlled, when the pH value of the condensed water in the heat preservation hot water tank 33 detected by the pH electrode 60 is not within the preset range of 7-8, the diaphragm metering pump 54 is automatically opened, so that the alkaline liquid is transmitted into the heat preservation hot water tank 33, when the pH value of the condensed water in the heat preservation hot water tank 33 detected by the pH electrode 60 is within the preset range of 7-8, the diaphragm metering pump 54 is automatically closed, the mixing speed of the alkaline medicament and the water in the dosing tank 49 can be accelerated by arranging the second stirrer 61, and the first stirrer 46 is arranged in the heat preservation hot water tank 33, so that the mixing speed of the alkaline liquid and the condensed water can be accelerated, the mixing efficiency is improved, and the condensed water can be conveniently and rapidly put into use.

Example 3

On the basis of embodiment 1 or 2, as shown in fig. 6 to 9, the water collection tank 6 is provided in a cylindrical shape, and an automatic cleaning mechanism is provided in the water collection tank 6, and the automatic cleaning mechanism includes:

the first rotating shaft 65 is arranged at the lower right of the water inlet 7, the front end and the rear end of the first rotating shaft 65 are respectively and rotatably connected with the inner walls of the front side and the rear side of the water collecting tank 6, a turbine 66 and a first gear 67 are sequentially arranged on the first rotating shaft 65 from back to front, the first gear 67 is an incomplete gear, and a left blade of the turbine 66 is positioned under the water inlet 7;

a second rotating shaft 68, the second rotating shaft 68 is arranged on the right of the first rotating shaft 65, the second rotating shaft 68 is parallel to the first rotating shaft 65, the rear end of the second rotating shaft 68 is rotatably connected with the inner wall of the rear side of the collecting water tank 6, a second gear 69 and a first bevel gear 70 are sequentially arranged on the second rotating shaft 68 from back to front, and the second gear 69 is intermittently meshed with the first gear 67;

a winding drum 71, wherein the winding drum 71 is arranged in front of the second rotating shaft 68, the upper end and the lower end of the winding drum 71 are respectively rotatably connected with the inner walls of the upper side and the lower side of the water collecting tank 6, a second bevel gear 72 is arranged on the winding drum 71, and the second bevel gear 72 is meshed with the first bevel gear 70;

the two sleeves 73 are symmetrically arranged on the outer walls of the front side and the rear side of the first drainage pipe 8, one end of each sleeve 73 is hinged with the outer wall of the first drainage pipe 8, the other end of each sleeve 73 is provided with a sliding column 74, and one end of each sliding column 74 is slidably connected with the inner wall of each sleeve 73;

a first spring 75, wherein the first spring 75 is arranged in the sleeve 73, one end of the first spring 75 is fixedly connected with one end of the sleeve 73 close to the first drain pipe 8, and the other end of the first spring 75 is fixedly connected with one end of the sliding column 74 in the sleeve 73;

a first scraping blade 76, wherein the first scraping blade 76 is arranged at one end of the sliding column 74 far away from the first drainage pipe 8, and the side wall of the first scraping blade 76 is in contact with the side wall of the collecting water tank 6;

the second spring 77 is arranged on the outer wall of the right side of the sleeve 73, one end of the second spring 77 is fixedly connected with the inner wall of the right side of the collecting water tank 6, and the other end of the second spring 77 is fixedly connected with the outer wall of the right side of the sleeve 73;

one end of the first steel wire rope 78 is fixedly connected with the outer wall of the left side of the sleeve 73, the other end of the first steel wire rope 78 is fixedly connected with the outer wall of the winding drum 71, and the first steel wire rope 78 is wound on the outer wall of the winding drum 71;

the fixing rod 79 is arranged in the first drainage pipe 8, the front end and the rear end of the fixing rod 79 are fixedly connected with the inner walls of the front side and the rear side of the first drainage pipe 8 respectively, the center of the fixing rod 79 is provided with a first sliding hole 80, the first sliding hole 80 penetrates through the left surface and the right surface of the fixing rod 79, a sliding rod 81 is connected in the first sliding hole 80 in a sliding mode, one end of the sliding rod 81 extends to the lower portion of the fixing rod 79 and is fixedly connected with one end of a second steel wire rope 82, the other end of the second steel wire rope 82 is fixedly connected with the outer wall of the winding drum 71, the second steel wire rope 82 is wound on the outer wall of the winding drum 71, and one end, far away from the second steel wire rope 82, of the sliding rod 81 extends to the right side of the fixing rod 79 and is provided with a limiting plate 83;

a sliding block 84, a second sliding hole 85 is arranged in the center of the sliding block 84, the sliding block 84 is sleeved on the sliding rod 81 through the second sliding hole 85 and is in sliding connection with the sliding rod 81, second scraping pieces 86 are obliquely arranged on the front side wall and the rear side wall of the sliding block 84, the second scraping pieces 86 are hinged to the side wall of the sliding block 84 near the center, a third spring 87 is arranged on the right side of the sliding block 84, one end of the third spring 87 is fixedly connected with the right side of the sliding block 84, and the other end of the third spring 87 is fixedly connected with the left side wall of the limit plate 83;

and the fourth spring 88 is arranged between the sliding block 84 and the fixing rod 79, one end of the fourth spring 88 is fixedly connected with the left side wall of the sliding block 84, and the other end of the fourth spring 88 is fixedly connected with the right side wall of the fixing rod 79.

The working principle and the beneficial effects of the technical scheme are as follows: when the condensed water flows into the collecting water tank 6 from the water inlet 7, the condensed water flows to drive the turbine 66 to rotate, the turbine 66 rotates to drive the first rotating shaft 65 to rotate, the first rotating shaft 65 rotates to drive the first gear 67 to rotate, the first gear 67 is intermittently meshed with the second gear 69, when the first gear 67 is meshed with the second gear 69, the first gear 67 rotates to drive the second gear 69 to rotate, the second gear 69 rotates to drive the second rotating shaft 68 to rotate, the second rotating shaft 68 rotates to drive the first bevel gear 70 to rotate, the first bevel gear 70 rotates to drive the second bevel gear 72 to rotate, the second bevel gear 72 rotates to drive the reel 71 to rotate, when the reel 71 rotates, the first steel wire rope 78 and the second steel wire rope 82 can be wound on the reel 71, the first steel wire rope 78 moves leftwards to drive the sleeve 73 to rotate by taking a hinged part with the outer wall of the first water drainage pipe 8 as a circle center, the sleeve 73 rotates to stretch the second spring 77, the sleeve 73 rotates to drive the sliding column 74 to rotate downwards, the sliding column 74 drives the first scraping blade 76 to slide downwards along the inner wall of the water collecting tank 6, under the action of the first spring 75, the side wall of the first scraping blade 76 is always in contact with the inner wall of the water collecting tank 6, meanwhile, the second steel wire rope 82 pulls the sliding rod 81 to move towards the direction away from the first drainage pipe 8, the sliding rod 81 slides in the first sliding hole 80 of the fixing rod 79 and drives the limiting plate 83 to move towards the left, when the limiting plate 83 moves to be in contact with the upper end of the second scraping blade 86, the limiting plate 83 can drive the second scraping blade 86 to rotate, the upper end of the second scraping blade 86 approaches towards the upper surface of the sliding block 84, and the third spring 87 is compressed, when the end, away from the third spring 87, of the second scraping blade 86 rotates to be in contact with the inner wall of the first drainage pipe 8, the second scraping blade 86 stops rotating, the limiting plate 83 continues to move towards the left, and drives the sliding block 84 to move towards the left along the sliding rod 81 through the second scraping blade 86, the fourth spring 88 is compressed, when the sliding block 84 moves leftwards, the side wall of the second scraping blade 86 can always contact with the inner wall of the first water drainage pipe 8, the first scraping blade 76 slides along the inner wall of the water collection tank 6 to scrape the scale attached to the inner wall of the water collection tank 6 off the inner wall, the inner wall of the water collection tank 6 is cleaned, the scale in the water collection tank 6 can be discharged from the first water drainage pipe 8, meanwhile, the second scraping blade 86 contacts with the inner wall of the first water drainage pipe 8 and slides leftwards along the inner wall of the first water drainage pipe 8, the second scraping blade 86 can scrape the scale attached to the inner wall of the first water drainage pipe 8 to discharge the scale from the first water drainage pipe 8, the scale on the inner wall of the water collection tank 6 is automatically collected in the process of collecting condensed water, the scale is cleared more thoroughly, the first water drainage pipe 8 can be prevented from being blocked by the scale, the first water drainage valve 9 is periodically opened, the scale in the first water drainage pipe 8 can be discharged, after the first gear 67 and the second gear 69 are engaged, the connecting column 30 and the sleeve 73 are restored under the action of the second spring 77, the sliding block 84 is restored under the action of the fourth spring 88, the limiting plate 83 is restored under the action of the third spring 87, and the first steel wire rope 78 and the second steel wire rope 82 are tensioned.

Example 4

On the basis of any one of embodiments 1-3, set up dust screen 89 in the water inlet 7, dust screen 89 periphery with water inlet 7 inner wall fixed connection, water inlet 7 department still sets up the monitoring subassembly, the monitoring subassembly is used for monitoring dust screen 89's jam degree, the monitoring subassembly includes:

the first flow detection device is arranged on one side, away from the interior of the collecting water tank 6, of the dust screen 89, and is used for detecting the first flow of condensed water on one side, away from the interior of the collecting water tank 6, of the dust screen 89;

the second flow detection device is arranged on one side, close to the interior of the collecting water tank 6, of the dustproof net 89, and is used for detecting a second flow of condensed water on one side, close to the interior of the collecting water tank 6, of the dustproof net 89;

the alarm is arranged on the outer wall of the water collecting tank 6;

the first controller is arranged on the outer wall of the collecting water tank 6 and is electrically connected with the first flow detection device, the second flow detection device and the alarm respectively;

the first controller controls the alarm to work based on the detection values of the first flow detection device and the second flow detection device, and comprises the following steps:

step 1: based on the detection values of the first flow rate detection device and the second flow rate detection device, the actual clogging degree value of the dust screen 89 is calculated by the following formula:

wherein,

is the actual clogging degree value of the dust screen 89, pi is the circumferential rate, pi is 3.14, r₁Is the cross-sectional radius of the water inlet 7, ln is a logarithmic function, H₂Is the height, H, of the water inlet 7₁Is the thickness, r, of the dust screen 89₂Is the radius of a single through hole in the dust screen 89, X is the total number of through holes on the dust screen 89, Q₁The first flow rate Q of the condensed water at the side of the dust screen 89 far away from the inside of the collecting water tank 6, which is detected by the first flow rate detecting device₂The prevention of detection for the second flow rate detecting meansA second flow of condensed water on one side of the dust screen 89 close to the interior of the water collection tank 6;

step 2: based on the calculation result of the step 1, the first controller compares the actual blockage degree value of the dust screen 89 with a preset blockage degree value, and when the actual blockage degree value is larger than the preset blockage degree value, the first controller controls the alarm to send out an alarm prompt.

The working principle and the beneficial effects of the technical scheme are as follows: because the water inlet 7 of the water collecting tank 6 is communicated with the outside, in order to avoid that dust enters the water collecting tank 6 through the water inlet 7 in the process of collecting condensed water, the dust screen 89 is arranged at the water inlet 7 and can block the dust on the outside, in addition, a monitoring component is also arranged at the water inlet 7 and can automatically monitor the blocking degree of the dust screen 89, the actual blocking degree value of the dust screen 89 can be calculated through the detection values of the first flow detection device and the second flow detection device, in the calculation process, the thickness of the dust screen 89 and the number and the radius of through holes in the dust screen 89 are comprehensively considered, under the same first flow of condensed water, the smaller the thickness of the dust screen 89 is, the larger the number of the through holes is, the larger the radius of the through holes is, the smaller the actual blocking degree value of the dust screen 89 is, the dust screen 89 is difficult to block, and based on the scheme, the actual blocking degree value of the dust screen 89 can be accurately calculated, then first controller carries out the comparison with actual jam degree value and predetermineeing the jam degree value, predetermines the jam degree value and is 0.8, when actual jam degree value is greater than predetermineeing the jam degree value, first controller control alarm sends the warning suggestion, the staff alright in time clear up dust screen 89 according to reporting to the police, prevent that dust screen 89 from blockking up and making the comdenstion water collect to collecting water tank 6 fast in, through alarm automatic alarm, the degree of automation of device is provided.

Example 5

On the basis of embodiment 4, as shown in fig. 10, a cleaning assembly is arranged in the collection water tank 6, the cleaning assembly is used for cleaning impurities on the lower surface of the dust screen 89, and the cleaning assembly includes:

the motor 90 is arranged on the inner wall of the top end of the water collection tank 6, the upper side wall of the motor 90 is fixedly connected with the inner wall of the top end of the water collection tank 6, an output shaft is arranged on the left side of the motor 90, the motor 90 is electrically connected with the first controller, and the motor 90 is a forward and reverse rotation motor;

one end of the screw rod 91 is fixedly connected with the output shaft, a sliding table 92 is arranged on the screw rod 91, and the sliding table 92 is in threaded transmission connection with the screw rod 91;

the mounting plate 93 is arranged at the left end of the sliding table 92, the length of the mounting plate 93 is greater than the diameter of the water inlet 7, and the cross-sectional area of the mounting plate 93 is greater than that of the water inlet 7;

the sliding strip 94 is fixedly arranged at the upper end of the sliding table 92, and the upper surface of the sliding strip 94 is in sliding connection with the inner wall of the top end of the collecting inner box 6;

the brush hair 95, the brush hair 95 sets up the mounting panel 93 upper surface, the brush hair 95 is provided with a plurality of, brush hair 95 one end with mounting panel 93 upper surface fixed connection, the brush hair 95 other end with dust screen 89 lower surface butt.

The working principle and the beneficial effects of the technical scheme are as follows: work as when the alarm sends the warning suggestion, first controller control motor 90 rotates, motor 90 can periodically carry out just reversing rotation in turn, motor 90 rotates and can drive screw rod 91 through the output shaft and rotate, screw rod 91 can drive slip table 92 when rotating and control reciprocating motion along screw rod 91 axis direction, and drive draw runner 94 along collecting 6 top inner walls of water tank and slide, slip table 92 motion can drive mounting panel 93 motion, mounting panel 93 drives brush hair 95 reciprocating motion about dust screen 89 lower surface, thereby clear up dust screen 89 lower surface, do not need artifical clearance dust screen 89 lower surface, the intensity of labour of staff has been alleviateed, and simultaneously, can control motor 90 through the alarm is reported to the police and open automatically, treat that the alarm is relieved back motor 90 self-closing, the degree of automation of device has been improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. A novel condensate water regeneration device is characterized by comprising: collect subassembly (1), filtering component (2), soften subassembly (3) and heat preservation subassembly (4), collect subassembly (1) filtering component (2) soften subassembly (3) and heat preservation subassembly (4) are turned right from a left side and are linked together the setting in proper order, heat preservation subassembly (4) output and boiler (5) input intercommunication.

2. A new condensate water regenerating device according to claim 1, characterized in that the collecting assembly (1) comprises:

the system comprises a water collecting tank (6), a water inlet (7) and a first drainage pipe (8) are arranged on the side wall of the water collecting tank (6), and a first drainage valve (9) is arranged at the position of the first drainage pipe (8);

the first electronic liquid level controller (10), the first electronic liquid level controller (10) is arranged on the side wall of the water collection tank (6), and the first electronic liquid level controller (10) is used for detecting the actual liquid level of the condensed water in the water collection tank (6);

first outlet pipe (11), first outlet pipe (11) set up collection water tank (6) right side is close to the lower extreme position, set up first ball valve (12) on first outlet pipe (11), first outlet pipe (11) one end with collection water tank (6) inside intercommunication, first outlet pipe (11) other end and first force (forcing) pump (13) input intercommunication, first force (forcing) pump (13) with first electron liquid level controller (10) electric connection.

3. A new condensate regenerating device according to claim 2, characterized in that the filter assembly (2) comprises:

the precision filter (14) is arranged on the right side of the collecting water tank (6), a precision filter bag (15) is arranged inside the precision filter (14), a first pressure gauge (16) is arranged at the upper end of the precision filter (14), a first water filtering pipe (17) is arranged on the left side of the precision filter (14), a second ball valve (18) is arranged on the first water filtering pipe (17), one end of the first water filtering pipe (17) is communicated with the output end of the first pressure pump (13), the other end of the first water filtering pipe (17) is communicated with the inside of the precision filter (14), a second drain pipe (19) is arranged on the right side of the precision filter (14), and a second drain valve (20) is arranged at the second drain pipe (19);

RO reverse osmosis filter (21), RO reverse osmosis filter (21) set up precision filter (14) right side, RO reverse osmosis filter (21) input pass through second water filter pipe (22) with precision filter (14) communicate, RO reverse osmosis filter (21) output sets up third water filter pipe (23), third water filter pipe (23) one end with RO reverse osmosis filter (21) output intercommunication.

4. The new condensate water regenerating device as claimed in claim 3, characterized in that, several RO reverse osmosis filters (21) are provided, and several RO reverse osmosis filters (21) are communicated with each other in sequence.

5. A new condensate water regenerating device according to claim 3, characterized in that the softening assembly (3) comprises:

the high-temperature-resistant resin filter (24), the high-temperature-resistant resin filter (24) is at least provided with two groups, two groups of high-temperature-resistant resin filters (24) are sequentially communicated and arranged, a high-temperature-resistant resin layer is arranged in the high-temperature-resistant resin filter (24), a full-automatic softening valve (25) is arranged at the upper end of the high-temperature-resistant resin filter (24), the input end of the full-automatic softening valve (25) positioned on the left side is communicated with the end, far away from the RO reverse osmosis filter (21), of the third water filtering pipe (23), the output end of the full-automatic softening valve (25) positioned on the left side is communicated with the input end of the full-automatic softening valve (25) positioned on the right side, the output end of the full-automatic softening valve (25) positioned on the right side is provided with a first softening water pipe (26), one end of the first softening water pipe (26) is communicated with the output end of the full-automatic softening valve (25) positioned on the right side, the input ends of the full-automatic softening valves (25) are provided with a water inlet valve (27) and a second pressure gauge (28);

the salt box (29) is arranged outside the high-temperature-resistant resin filter (24), salt liquid is arranged in the salt box (29), a first overflow port (30) is formed in the side wall of the upper end of the salt box (29), the salt box (29) is communicated with the upper end of the high-temperature-resistant resin filter (24) through a second softened water pipe (31), and a salt suction valve is arranged on the second softened water pipe (31);

a third softening water pipe (32), one end of the third softening water pipe (32) is communicated with the upper end of the high-temperature-resistant resin filter (24), the other end of the third softening water pipe (32) is communicated with the outside of the high-temperature-resistant resin filter (24), and an upper discharge valve is arranged on the third softening water pipe (32).

6. The new condensate regenerating device according to claim 5, characterized in that the thermal insulation assembly (4) comprises:

a heat preservation hot water tank (33), the heat preservation hot water tank (33) is arranged on the right side of the high temperature resistant resin filter (24), the inner wall of the heat preservation hot water tank (33) is provided with a heat preservation layer, a first heat preservation water pipe (34) is arranged close to the upper position of the left side wall of the heat preservation hot water tank (33), one end of the first heat preservation water pipe (34) is communicated with one end of the first softening water pipe (26) far away from the full-automatic softening valve (25), the other end of the first heat-preservation water pipe (34) extends into the heat-preservation hot water tank (33) and is provided with a first ball float valve (35), a sampling valve (36) is arranged on the first heat-preservation water pipe (34), a third drain pipe (37) is arranged on the side wall of the heat-preservation hot water tank (33) close to the lower end, a third drain valve (38) is arranged at the third drain pipe (37), and a second overflow port (39) is arranged on the right side wall of the heat-preservation hot water tank (33) close to the upper end;

the second electronic liquid level controller (40), the second electronic liquid level controller (40) is arranged on the side wall of the heat preservation hot water tank (33), and the second electronic liquid level controller (40) is used for detecting the actual liquid level of the condensed water in the heat preservation hot water tank (33);

one end of the second heat-preservation water pipe (41) is fixedly connected with the side wall, close to the lower end, of the heat-preservation hot water tank (33), one end of the second heat-preservation water pipe (41) is communicated with the interior of the heat-preservation hot water tank (33), the other end of the second heat-preservation water pipe (41) is communicated with the input end of a water pump (42), the output end of the water pump (42) is provided with a third heat-preservation water pipe (43), one end of the third heat-preservation water pipe (43) is communicated with the output end of the water pump (42), and the other end of the third heat-preservation water pipe (43) is communicated with the input end of the boiler (5);

the third ball valve (44), the said third ball valve (44) is set up on the said second insulating water pipe (41);

and the fourth ball valve (45), wherein the fourth ball valve (45) is arranged on the third heat-preservation water pipe (43).

7. The novel condensate water regenerating device as claimed in claim 6, characterized in that a first stirring shaft (46) is arranged on the heat preservation hot water tank (33), a first stirring shaft (47) is arranged at the output end of the first stirring shaft (46), one end of the first stirring shaft (47) extends into the heat preservation hot water tank (33) and a plurality of first stirring blades (48) are arranged.

8. The novel condensate water regenerating device of claim 6, further comprising a dosing assembly, said dosing assembly comprising:

a dosing box (49), wherein a second water inlet pipe (50) is arranged on the left side wall of the dosing box (49) close to the upper end, and the output end of the second water inlet pipe (50) extends into the dosing box (49) and is provided with a second ball float valve (51);

the medicine feeding port (52) is arranged at the upper end of the medicine feeding box (49), and the medicine feeding port (52) is communicated with the upper end of the medicine feeding box (49);

one end of the first dosing pipe (53) extends to a position close to the bottom wall inside the dosing box (49) and is communicated with the inside of the dosing box (49), the other end of the first dosing pipe (53) penetrates through the top wall of the dosing box (49), extends to the outside of the dosing box (49) and is communicated with the input end of a diaphragm metering pump (54), and a fifth ball valve (55) is arranged on the first dosing pipe (53);

one end of the second dosing pipe (56) is communicated with the output end of the diaphragm metering pump (54), the other end of the second dosing pipe (56) penetrates through the top wall of the heat-preservation hot water tank (33), extends into the heat-preservation hot water tank (33) and is communicated with the interior of the heat-preservation hot water tank (33), and a sixth ball valve (57) is arranged on the second dosing pipe (56);

alternating current contactor (58), alternating current contactor (58) output with diaphragm metering pump (54) input electric connection, alternating current contactor (58) input and pH detector (59) output electric connection, pH detector (59) input sets up pH electrode (60), pH electrode (60) are located inside heat preservation hot-water tank (33), pH electrode (60) output with pH detector (59) input electric connection.

9. The new condensate water regenerating device as claimed in claim 8, characterized in that a second stirrer (61) is arranged on the feed box (49), a second stirring shaft (62) is arranged at the output end of the second stirrer (61), one end of the second stirring shaft (62) extends to the interior of the feed box (49) and is provided with a plurality of second stirring blades (63).

10. The new condensate regenerating device as claimed in claim 2, characterized in that the collecting tank (6) is provided in a cylindrical shape, and an automatic cleaning mechanism is provided in the collecting tank (6), and the automatic cleaning mechanism comprises:

the first rotating shaft (65), the first rotating shaft (65) is arranged at the lower right of the water inlet (7), the front end and the rear end of the first rotating shaft (65) are respectively and rotatably connected with the inner walls of the front side and the rear side of the water collecting tank (6), a turbine (66) and a first gear (67) are sequentially arranged on the first rotating shaft (65) from back to front, the first gear (67) is an incomplete gear, and left blades of the turbine (66) are positioned under the water inlet (7);

the second rotating shaft (68) is arranged on the right side of the first rotating shaft (65), the second rotating shaft (68) is parallel to the first rotating shaft (65), the rear end of the second rotating shaft (68) is rotatably connected with the inner wall of the rear side of the collecting water tank (6), a second gear (69) and a first bevel gear (70) are sequentially arranged on the second rotating shaft (68) from back to front, and the second gear (69) is intermittently meshed with the first gear (67);

the winding drum (71), the winding drum (71) is arranged in front of the second rotating shaft (68), the upper end and the lower end of the winding drum (71) are respectively in rotating connection with the inner walls of the upper side and the lower side of the water collecting tank (6), a second bevel gear (72) is arranged on the winding drum (71), and the second bevel gear (72) is meshed with the first bevel gear (70);

the two sleeves (73) are symmetrically arranged on the outer walls of the front side and the rear side of the first drainage pipe (8), one end of each sleeve (73) is hinged with the outer wall of the first drainage pipe (8), the other end of each sleeve (73) is provided with a sliding column (74), and one end of each sliding column (74) is connected with the inner wall of each sleeve (73) in a sliding manner;

the first spring (75) is arranged in the sleeve (73), one end of the first spring (75) is fixedly connected with one end, close to the first drainage pipe (8), of the sleeve (73), and the other end of the first spring (75) is fixedly connected with one end, located in the sleeve (73), of the sliding column (74);

the first scraping blade (76) is arranged at one end, far away from the first drainage pipe (8), of the sliding column (74), and the side wall of the first scraping blade (76) is in contact with the side wall of the collecting water tank (6);

the second spring (77) is arranged on the outer wall of the right side of the sleeve (73), one end of the second spring (77) is fixedly connected with the inner wall of the right side of the water collecting tank (6), and the other end of the second spring (77) is fixedly connected with the outer wall of the right side of the sleeve (73);

one end of the first steel wire rope (78) is fixedly connected with the outer wall of the left side of the sleeve (73), the other end of the first steel wire rope (78) is fixedly connected with the outer wall of the winding drum (71), and the first steel wire rope (78) is wound on the outer wall of the winding drum (71);

a fixing lever (79), the fixing lever (79) being disposed in the first drain pipe (8), the front end and the rear end of the fixed rod (79) are respectively fixedly connected with the inner walls of the front side and the rear side of the first drainage pipe (8), a first sliding hole (80) is formed in the center of the fixing rod (79), the first sliding hole (80) penetrates through the left surface and the right surface of the fixing rod (79), a sliding rod (81) is connected in the first sliding hole (80) in a sliding way, one end of the sliding rod (81) extends to the lower part of the fixed rod (79) and is fixedly connected with one end of a second steel wire rope (82), the other end of the second steel wire rope (82) is fixedly connected with the outer wall of the winding drum (71), the second steel wire rope (82) is wound on the outer wall of the winding drum (71), one end, far away from the second steel wire rope (82), of the sliding rod (81) extends to the right side of the fixing rod (79) and is provided with a limiting plate (83);

the sliding block (84) is provided with a second sliding hole (85) in the center, the sliding block (84) is sleeved on the sliding rod (81) through the second sliding hole (85) and is in sliding connection with the sliding rod (81), the front side wall and the rear side wall of the sliding block (84) are obliquely provided with second scraping pieces (86), the second scraping pieces (86) are hinged to the side wall of the sliding block (84) near the center, the right side of the sliding block (84) is provided with a third spring (87), one end of the third spring (87) is fixedly connected with the right side of the sliding block (84), and the other end of the third spring (87) is fixedly connected with the left side wall of the limiting plate (83);

the fourth spring (88), the fourth spring (88) sets up between slider (84) and dead lever (79), fourth spring (88) one end with slider (84) left side wall fixed connection, the fourth spring (88) other end with dead lever (79) right side wall fixed connection.