CN212408808U - Integrated heating safety system - Google Patents

Integrated heating safety system Download PDF

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CN212408808U
CN212408808U CN202021010993.8U CN202021010993U CN212408808U CN 212408808 U CN212408808 U CN 212408808U CN 202021010993 U CN202021010993 U CN 202021010993U CN 212408808 U CN212408808 U CN 212408808U
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clear liquid
filter
water tank
precipitation
water
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孙光武
陈立波
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Qingdao Ruiante Environmental Protection Co ltd
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Qingdao Ruiante Environmental Protection Co ltd
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Abstract

The utility model provides an integration heating safety coefficient, this heating safety coefficient includes: a high precision filter to produce a primary precipitate and a primary clear liquid; the first precipitation water tank is used for receiving primary precipitation generated by filtering of the high-precision filter; a descaling device for generating secondary precipitation and secondary clear liquid; the exhaust tank is used for receiving the secondary clear liquid generated in the descaling device and performing exhaust treatment on the secondary clear liquid to obtain tertiary clear liquid; the second precipitation water tank is used for receiving secondary precipitation generated in the descaling device; the filter press is used for receiving the primary precipitate in the first precipitation water tank and the secondary precipitate in the second precipitation water tank, and performing filter pressing on the primary precipitate and the secondary precipitate to obtain a filter cake and a fourth clear liquid; the recycle water tank for receive the quartic clear liquid that produces in the filter press and with quartic clear liquid conveying return high accuracy filter, borrow this, the utility model has the advantages of can avoid entering into the inside water of second grade net and appear deposiing.

Description

Integrated heating safety system
Technical Field
The utility model belongs to the technical field of heating auxiliary assembly, in particular to integration heating safety coefficient.
Background
At present, a conventional heating system is composed of a primary network and a secondary network, wherein the primary network is used for providing high-temperature and high-pressure hot water or steam by a thermal power plant (a heat source plant), and the hot water or the steam in the primary network is completely subjected to chemical treatment and is not easy to scale and corrode. The water supplemented by the secondary network is tap water or industrial water which is not treated, the tap water or industrial water is sent to users after heat exchange by a heat exchange station heat exchange unit of the primary network, particularly, more and more heat users are used after living rooms are improved, so that the secondary network is increased year by year and is frequently improved, the secondary network is added with a buried mode, belongs to a hidden project, and is inevitably introduced with impurities such as silt, welding slag and the like in the improvement and extension processes, the secondary network is generally of a buried structure, a flushing pipeline cannot be flushed completely, circulating water does not have an effective filtering device before entering the heat exchange unit, so that the impurities such as the silt and the like are deposited in the heat exchange unit, the silt and other wastes in the pipe network after the overhaul or the improvement of the pipe network cannot be thoroughly removed, therefore, the silt and the like are deposited in the heat exchange unit after the heat exchange unit is put into operation, the water under the deposit is gradually evaporated, the concentrations of calcium, cause the heat exchanger scale deposit, silt, debris, aquatic calcium magnesium ion is too high will cause the heat exchanger group of second grade net at heat exchange station to generate sediment and sediment, take place scale deposit blocking phenomenon, the scale deposit of heat exchanger group is blockked up not only to influence the heat transfer effect and is reduced the heating temperature, reduce the circulation volume of second grade net, cause the heat exchanger to scrap and the heating interrupt when serious, so all need overhaul heat exchanger group after the heating of every year, clear away sediment and sediment, therefore the sediment of second grade net and the serious restriction heating system safe operation of silt deposit.
And the circulating water of the secondary network generally adopts industrial water, and is not chemically treated, so that calcium, magnesium ions and alkalinity in the water are higher, the ions can scale on the heat exchange unit, particularly a steam heat exchange unit, the scaling in the secondary network in the hot water heat exchange unit is not serious, but attachments are arranged on the heat exchange surface of the heat exchange unit, the scaling phenomenon can also occur under the attachments, chemical medicines have possible environmental pollution and harm to human health when the secondary network is cleaned, waste liquid after chemical cleaning cannot be directly discharged, the waste liquid can be discharged only after reaching the standard after treatment, otherwise secondary pollution to the environment can be caused, the heat exchange effect of the secondary network in the heat exchange unit is unstable, once scaling and sediment deposition occur, the heat exchange effect can be obviously reduced, heat supply interruption can be caused by withdrawing operation in serious cases, and the safe and stable operation of the whole heat supply system is influenced.
SUMMERY OF THE UTILITY MODEL
The utility model provides an integration heating safety coefficient can avoid entering into the inside water of second grade net problem that appears precipitating and lead to the unable safe operation of heating system.
The technical scheme of the utility model is realized like this: the integrated heating safety system is communicated with a secondary network of the heating system, and comprises:
a high precision filter for receiving and filtering untreated water to produce a primary precipitate and a primary clear liquid;
the first precipitation water tank is communicated with the bottom of the high-precision filter and used for receiving primary precipitation generated by filtering of the high-precision filter;
the descaling device is communicated with one side of the high-precision filter and is used for receiving primary clear liquid generated in the high-precision filter and descaling the primary clear liquid to generate secondary precipitation and secondary clear liquid;
the exhaust tank is communicated with one side of the descaling device and is used for receiving secondary clear liquid generated in the descaling device and performing exhaust treatment on the secondary clear liquid to obtain tertiary clear liquid;
the second precipitation water tank is communicated with the bottom of the descaling device and used for receiving secondary precipitation generated in the descaling device;
the filter press is communicated between the first precipitation water tank and the second precipitation water tank and is used for receiving the primary precipitation in the first precipitation water tank and the secondary precipitation in the second precipitation water tank and carrying out filter pressing on the primary precipitation and the secondary precipitation to obtain a filter cake and four times of clear liquid;
and the recovery water tank is communicated and arranged between the filter press and the high-precision filter and is used for receiving the quartic clear liquid generated in the filter press and transmitting the quartic clear liquid back to the high-precision filter.
Before entering a heat exchange unit, circulating water of a secondary net firstly passes through a high-precision filter, a descaling device and an exhaust tank to remove impurities such as silt in the water and reduce calcium and magnesium scaling ions in the water and then enters a secondary net of the heat exchange unit to be heated, before entering the heat exchange unit, the circulating water of the secondary net firstly enters the high-precision filter to carry out self-precipitation, large particles such as silt in the water and relatively small particles in the water are preliminarily separated in the high-precision filter and then enter a filtering component in the high-precision filter, the impurities in the water can be further filtered by the filtering component, the generated precipitate is once precipitated, water generated in the process is primary clear liquid, when the pressure of the water flowing out of the high-precision filter is reduced to a certain degree, the high-precision filter stops filtering, and an ultrasonic cleaning rod is started to clean the filtering net, cleaning for a certain time to generate precipitates which are primary precipitates and are discharged into a shell, then sequentially discharging the precipitates into a first precipitation water tank, feeding primary clear liquid generated in a high-precision filter into a descaling device for descaling, wherein the precipitates generated by descaling are secondary precipitates, the generated clear liquid is secondary clear liquid and is transmitted into an exhaust tank, the exhaust tank is used for degassing the second clear liquid to generate third clear liquid, and finally the third clear liquid is fed into a secondary network of a heat exchange unit, so that the problems of silt deposition and scaling in the secondary network of the heat exchange unit are thoroughly avoided, the secondary precipitates generated in the descaling device are discharged into a second precipitation water tank, the primary precipitates and the secondary precipitates received in the first precipitation water tank and the second precipitation water tank are fed into a filter press, and the filter press is used for filter pressing the primary precipitates and the secondary precipitates to obtain filter cakes and four times of clear liquid, the four times of clear liquid can be refilled into the high-precision filter for reuse, so that the waste of water resources is avoided.
As a preferred embodiment, the high-precision filter comprises an external shell, a water inlet pipe is communicated with the left side of the lower part of the shell, a plurality of uniformly distributed filter components are fixedly arranged in the shell, each filter component comprises an outer cylindrical filter screen and an ultrasonic cleaning rod fixedly arranged in the filter screen, the bottoms of the filter screens and the bottom of the inner side of the shell are arranged at intervals, one side of each filter screen is communicated with a water outlet pipe, one end of each water outlet pipe penetrates out of the shell and is communicated with a descaling device, the shell of the filtering system, the filter screens and the ultrasonic cleaning rods are arranged in the shell, impurities in water are primarily separated at the lower part of the shell by virtue of the gravity of the particles, the particles with the size of silt and the like become primary precipitate in the shell and then flow into a settling tank through the bottom of the shell for deposition, and the separated clean water is subjected to high-precision filtration by a filter screen, after filtering for a long time, the filter screen surface can adhere to impurity, when producing water pressure and reducing to a certain extent, the operation of ultrasonic cleaning stick is washd the filter screen, and the pollutant of adhering to on the filter screen is clear away, and the impurity on filter screen surface enters into once in the precipitation water tank along with once depositing, and the outlet pipe discharge is followed to a clear liquid for whole filtering process is more accurate.
As a preferred embodiment, the descaling device comprises two descaling devices which are arranged at left and right intervals, wherein the top of the descaling device on the left side is communicated with the bottom of the descaling device on the right side, each descaling device comprises a shell, a plurality of uniformly distributed cylindrical cathode nets are fixedly arranged on the upper part of the inner side of the shell, cylindrical anode nets are sleeved on the outer sides of the cathode nets, the tops of the anode nets are fixedly connected with the top of the shell, a water distribution plate is fixedly arranged on the lower part of the inner side of the shell, through holes which correspond to the anodes and are circular are arranged on the water distribution plate, the diameters of the through holes are the same as those of the cathodes, a water production pipe is communicated with the right side of the top of the shell, the water production pipe is communicated with an exhaust tank, the bottom of each shell is communicated with the top of a second precipitation water tank, a water inlet hole arranged on the shell of the descaling device receives primary clear liquid, the cathode and the anode treat the primary clear liquid, calcium and magnesium ions in the primary clear liquid are separated out, the primary clear liquid becomes secondary clear liquid and enters the exhaust tank from the water production pipe, and the two descaling devices are arranged, namely, the primary clear liquid is descaled twice, so that the secondary clear liquid is cleaner.
As a preferred embodiment, the bottom of the shell on the left side and the bottom of the shell on the right side are both provided with water inlet holes, the water outlet pipe is communicated with the water inlet hole in the bottom of the shell on the left side, the water production pipe is communicated with the water inlet hole in the bottom of the shell on the right side, and the water outlet pipe sends primary clear liquid into the shell through the water inlet holes, so that the primary clear liquid is conveniently treated by the cathode and the anode in the shell.
As a preferred implementation mode, a first sewage discharge valve is fixedly arranged between the descaling devices on the left side and the right side and the top of the second precipitation water tank respectively, a second sewage discharge valve is fixedly arranged between the bottom of the high-precision filter and the first precipitation water tank, the first sewage discharge valve and the second sewage discharge valve can be opened as required, and secondary precipitation generated in the descaling devices is discharged into the secondary precipitation water tank.
As a preferred embodiment, a first valve is fixedly arranged between the filter press and the first settling water tank, a second valve is fixedly arranged between the second settling water tank and the filter press, and the first valve and the second valve are independently opened, so that the filter press can avoid mutual influence when the filter press can respectively process primary settling in the first settling water tank and secondary settling in the second settling water tank.
As a preferred embodiment, the right sides of the top parts of the first settling water tank, the second settling water tank and the exhaust tank are provided with exhaust pipes, exhaust valves are fixedly arranged on the exhaust pipes, the exhaust valves can be opened as required to exhaust, and damage caused by overhigh air pressure in the equipment is avoided.
In a preferred embodiment, a water supply pipe is communicated with the right side of the bottom of the exhaust tank, and the water supply pipe is communicated with the secondary net and transfers the tertiary clear liquid into the secondary net.
After the technical scheme is adopted, the beneficial effects of the utility model are that:
1. the problem of sediment deposition in the heat exchange unit of the secondary network is solved through the arrangement of the high-precision filtering device and the descaling device;
2. the service life of the heat exchange equipment is prolonged, and the secondary network does not need to be frequently disassembled and inspected and washed by high-pressure water, so that the service life of the heat exchange equipment is greatly prolonged.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.
Fig. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic view of the high-precision filter of FIG. 1;
FIG. 3 is a schematic view of the descaling device shown in FIG. 1;
FIG. 4 is an enlarged schematic view of portion A of FIG. 3;
fig. 5 is a schematic structural view of the exhaust canister of fig. 1.
In the figure, 1-high precision filter; 2-a first settling water tank; 3-a descaling device; 4-an exhaust tank; 5-a second settling water tank; 6, a filter press; 7-a recovery water tank; 8-an exhaust pipe; 11-a housing; 12-a water inlet pipe; 13-a filter assembly; 14-a water outlet pipe; 21-a second blowoff valve; 31-a housing; 32-cathode mesh; 33-an anode mesh; 34-a water distribution plate; 35-water inlet hole; 41-water supply pipe; 51-a first purge valve; 61-a first valve; 62-a second valve; 81-exhaust valve; 131-a filter screen; 132-ultrasonic cleaning rod; 341-through hole.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.
As shown in fig. 1 to 5, the integrated heating safety system is connected to a secondary grid of a heating system, and includes:
a high-precision filter 1 for receiving untreated water and filtering the untreated water to produce a primary precipitate and a primary clear liquid;
the first precipitation water tank 52 is communicated with the bottom of the high-precision filter 1 and is used for receiving primary precipitation generated by filtering of the high-precision filter 1;
the descaling device 3 is communicated with one side of the high-precision filter 1 and is used for receiving the primary clear liquid generated in the high-precision filter 1 and descaling the primary clear liquid to generate secondary precipitation and secondary clear liquid;
the exhaust tank 4 is communicated with one side of the descaling device 3 and is used for receiving the secondary clear liquid generated in the descaling device 3 and performing exhaust treatment on the secondary clear liquid to obtain a tertiary clear liquid;
the second precipitation water tank 5 is communicated with the bottom of the descaling device 3 and is used for receiving secondary precipitation generated in the descaling device 3;
the filter press 6 is communicated between the first settling water tank 52 and the second settling water tank 5, and is used for receiving the primary sedimentation in the first settling water tank 52 and the secondary sedimentation in the second settling water tank 5, and performing filter pressing on the primary sedimentation and the secondary sedimentation to obtain a filter cake and four times of clear liquid;
and a recovery water tank 7 capable of temporarily storing the quartic clear liquid to avoid discharge of the quartic clear liquid, disposed in communication between the filter press 6 and the high-precision filter 1, for receiving the quartic clear liquid generated in the filter press 6 and transferring the quartic clear liquid back into the high-precision filter 1.
Before entering the heat exchanger set, the circulating water of the secondary network firstly passes through the high-precision filter 1, the descaling device 3 and the exhaust tank 4 to remove impurities such as silt in the water and reduce calcium and magnesium scaling ions in the water and then enters the secondary network of the heat exchanger set to be heated, before entering the heat exchanger set, the circulating water of the secondary network firstly enters the high-precision filter 1 to carry out self-precipitation, large particles such as silt in the water and relatively small particles in the water are preliminarily separated in the high-precision filter 1 and then enter the filtering component 13 in the high-precision filter 1, the impurities in the water are further filtered by the filtering component 13, the generated precipitate is simultaneously precipitated, the water generated in the process is primary clear liquid, when the pressure of the water flowing out of the high-precision filter 1 is reduced to a certain degree, the high-precision filter 1 stops filtering, the ultrasonic cleaning rod 132 is started to clean the filtering net 131, cleaning for a certain time to generate precipitates which are primary precipitates and are discharged into the shell 11, then sequentially discharging the precipitates into a first precipitation water tank 52, feeding primary clear liquid generated in the high-precision filter 1 into a descaling device 3 for descaling treatment, wherein the precipitates generated by descaling are secondary precipitates, the generated clear liquid is secondary clear liquid and is transmitted into an exhaust tank 4, the exhaust tank 4 carries out degassing on the second clear liquid to generate third clear liquid, and finally the third clear liquid enters a secondary network of a heat exchange unit, so that the problems of sediment deposition and scaling in the secondary network of the heat exchange unit are thoroughly avoided, the secondary precipitates generated in the descaling device 3 are discharged into a second precipitation water tank 5, the primary precipitates and the secondary precipitates received in the first precipitation water tank 52 and the second precipitation water tank 5 enter a filter press 6, and the primary precipitates and the secondary precipitates are subjected to filter press by the filter press 6, and a filter cake and four times of clear liquid are obtained, and the four times of clear liquid can be refilled into the high-precision filter 1 for reuse, so that the waste of water resources is avoided.
The high-precision filter 1 comprises an external shell 11, a water inlet pipe 12 is communicated with the left side of the lower part of the shell 11, a plurality of uniformly distributed filter components 13 are fixedly arranged in the shell 11, each filter component 13 comprises a cylindrical filter screen 131 at the outer side and an ultrasonic cleaning rod 132 fixedly arranged in the filter screen 131, the bottoms of the filter screens 131 and the bottom of the inner side of the shell 11 are arranged at intervals, a water outlet pipe 14 is communicated with one side of each filter screen 131, one end of each water outlet pipe 14 penetrates out of the shell 11 and is communicated with a descaling device 3, the shell 11 of the filtering system, the filter screens 131 and the ultrasonic cleaning rods 132 allow water to enter the shell 11 from the water inlet pipe 12, impurities in the water are primarily separated at the lower part of the shell 11 by virtue of the gravity of the particles, the particles such as silt and the like become primary precipitate in, clear water after the separation carries out high-accuracy filtration through filter screen 131 that 0.5-5um316L stainless steel made, after filtering for a long time, filter screen 131 surface can adhere to impurity, when producing water pressure and reducing to a certain extent, ultrasonic cleaning stick 132 operation, wash filter screen 131, the pollutant of adhering to on the filter screen is clear away, the impurity on filter screen 131 surface enters into once along with once depositing in the water tank, a clear liquid is discharged from outlet pipe 14, make whole filtering process more accurate.
The descaling devices 3 comprise two descaling devices 3 arranged at left and right intervals, wherein the top of the descaling device 3 on the left side is communicated with the bottom of the descaling device 3 on the right side, each descaling device 3 comprises a shell 31, the upper part of the inner side of the shell 31 is fixedly provided with a plurality of uniformly distributed cylindrical cathode nets 32, the outer sides of the cathode nets 32 are sleeved with cylindrical anode nets 33, the top of each anode net 33 is fixedly connected with the top of the shell 31, the lower part of the inner side of the shell 31 is fixedly provided with a water distribution plate 34, the water distribution plate 34 is provided with circular through holes 341 corresponding to the anodes, the diameter of each through hole 341 is the same as that of each cathode, the right side of the top of the shell 31 is communicated with a water production pipe, the water production pipe is communicated with the exhaust tank 4, the bottom of each shell 31 is communicated with the top of the second precipitation water tank 5, water inlet holes 35 arranged on the shell, then the water enters between the cathode and the anode through the through holes 341 on the water distribution plate 34, the cathode and the anode process the primary clear liquid to separate out calcium and magnesium ions in the primary clear liquid, at the moment, the primary clear liquid becomes secondary clear liquid and enters the exhaust tank 4 from the water production pipe, and the two descaling devices 3 are arranged, which is equivalent to carrying out two descaling treatments on the primary clear liquid, so that the secondary clear liquid is cleaner. The inlet opening 35 has all been seted up to the bottom of the shell 31 of the left and right sides, and outlet pipe 14 communicates with the inlet opening 35 of left shell 31 bottom, produces the inlet opening 35 intercommunication of water pipe and shell 31 bottom on right side, and outlet pipe 14 will be once in the clear liquid sends into shell 31 through inlet opening 35, makes things convenient for negative pole and the positive pole in the shell 31 to handle a clear liquid.
The first blowoff valve 51 is fixedly arranged between the descaling device 3 on the left side and the right side and the top of the second sedimentation water tank 5 respectively, the second blowoff valve 21 is fixedly arranged between the bottom of the high-precision filter 1 and the first sedimentation water tank 52, the first blowoff valve 51 and the second blowoff valve 21 can be opened as required, and the secondary sedimentation water generated in the descaling device 3 is discharged into the secondary sedimentation water tank. The first valve 61 is fixedly arranged between the filter press 6 and the first settling water tank 52, the second valve 62 is fixedly arranged between the second settling water tank 5 and the filter press 6, and the first valve 61 and the second valve 62 are independently opened, so that the filter press 6 can avoid mutual influence when the first settling in the first settling water tank 52 and the second settling in the second settling water tank are respectively treated by the filter press 6. The right side at first sediment water tank 52, second sediment water tank 5 and exhaust can 4 top all is provided with blast pipe 8, and the fixed discharge valve 81 that sets up on blast pipe 8 can open discharge valve 81 as required and exhaust, avoids the inside high atmospheric pressure of equipment to cause the damage. The right side of the bottom of the exhaust tank 4 is communicated with a water supply pipe 41, and the water supply pipe 41 is communicated with the secondary network and transmits the tertiary clear liquid into the secondary network.
In the description of the present invention, it is to be understood that the terms "longitudinal", "transverse", "upper" and "lower" are used herein,
Lower, front, rear, left, right, vertical, horizontal, top, bottom and inner,
The references to "outside" or the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. In the description of the present invention, unless otherwise specified and limited, it is to be noted that the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, mechanically or electrically connected, or may be connected between two elements through an intermediate medium, or may be directly connected or indirectly connected, and specific meanings of the terms may be understood by those skilled in the art according to specific situations.
The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. Integration heating safety coefficient with heating system's second grade net intercommunication, its characterized in that, this heating safety coefficient includes:
a high precision filter for receiving and filtering untreated water to produce a primary precipitate and a primary clear liquid;
the first precipitation water tank is communicated with the bottom of the high-precision filter and used for receiving primary precipitation generated by filtering of the high-precision filter;
the descaling device is communicated with one side of the high-precision filter and is used for receiving primary clear liquid generated in the high-precision filter and descaling the primary clear liquid to generate secondary precipitation and secondary clear liquid;
the exhaust tank is communicated with one side of the descaling device and is used for receiving secondary clear liquid generated in the descaling device and performing exhaust treatment on the secondary clear liquid to obtain tertiary clear liquid;
the second precipitation water tank is communicated with the bottom of the descaling device and used for receiving secondary precipitation generated in the descaling device;
the filter press is communicated between the first precipitation water tank and the second precipitation water tank and is used for receiving the primary precipitation in the first precipitation water tank and the secondary precipitation in the second precipitation water tank and carrying out filter pressing on the primary precipitation and the secondary precipitation to obtain a filter cake and four times of clear liquid;
and the recovery water tank is communicated and arranged between the filter press and the high-precision filter and is used for receiving the quartic clear liquid generated in the filter press and transmitting the quartic clear liquid back to the high-precision filter.
2. The integrated heating safety system according to claim 1, wherein the high-precision filter comprises an external shell, a water inlet pipe is arranged on the left side of the lower portion of the shell in a communicating mode, a plurality of uniformly distributed filter assemblies are fixedly arranged in the shell, each filter assembly comprises an outer cylindrical filter screen and an ultrasonic cleaning rod fixedly arranged in the filter screen, the bottom of each filter screen and the bottom of the inner side of the shell are arranged at intervals, a water outlet pipe is arranged on one side of each filter screen in a communicating mode, and one end of each water outlet pipe penetrates through the shell and is communicated with the descaling device.
3. The integrated heating safety system of claim 2, wherein the descaling device comprises two descaling devices which are arranged at a left-right interval, wherein the top of the descaling device on the left side is communicated with the bottom of the descaling device on the right side, each descaling device comprises a shell, a plurality of uniformly distributed cylindrical cathode nets are fixedly arranged at the upper part of the inner side of the shell, cylindrical anode nets are sleeved at the outer sides of the cathode nets, the top of the anode net is fixedly connected with the top of the shell, the lower part of the inner side of the shell is fixedly provided with a water distribution plate, the water distribution plate is provided with a circular through hole corresponding to the anode, the diameter of the through hole is the same as that of the cathode, the right side intercommunication at shell top is provided with produces the water pipe, produce water pipe and exhaust can intercommunication, every the bottom of shell all communicates with the top of second sedimentation water tank.
4. The integrated heating safety system according to claim 3, wherein the left and right housings are provided with water inlet holes at the bottoms thereof, the water outlet pipe is communicated with the water inlet hole at the bottom of the left housing, and the water production pipe is communicated with the water inlet hole at the bottom of the right housing.
5. The integrated heating safety system according to claim 3, wherein a first blowdown valve is fixedly arranged between the descaling device on the left side and the descaling device on the right side and the top of the second settling water tank respectively, and a second blowdown valve is fixedly arranged between the bottom of the high-precision filter and the first settling water tank.
6. The integrated heating safety system according to claim 1, wherein a first valve is fixedly arranged between the filter press and the first settling water tank, a second valve is fixedly arranged between the second settling water tank and the filter press, and the first valve and the second valve are independently opened.
7. The integrated heating safety system of claim 1, wherein the first settling water tank, the second settling water tank and the right side of the top of the exhaust tank are provided with exhaust pipes, and exhaust valves are fixedly arranged on the exhaust pipes.
8. The integrated heating safety system of claim 7, wherein a water supply pipe is provided in communication with the right side of the bottom of the exhaust tank.
CN202021010993.8U 2020-06-04 2020-06-04 Integrated heating safety system Active CN212408808U (en)

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Application Number Priority Date Filing Date Title
CN202021010993.8U CN212408808U (en) 2020-06-04 2020-06-04 Integrated heating safety system

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Application Number Priority Date Filing Date Title
CN202021010993.8U CN212408808U (en) 2020-06-04 2020-06-04 Integrated heating safety system

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Publication Number Publication Date
CN212408808U true CN212408808U (en) 2021-01-26

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Application Number Title Priority Date Filing Date
CN202021010993.8U Active CN212408808U (en) 2020-06-04 2020-06-04 Integrated heating safety system

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114413324A (en) * 2022-02-22 2022-04-29 南京港华能源投资发展有限公司第一分公司 Data analysis system and method for efficient central heating of cold and heat source machine room

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114413324A (en) * 2022-02-22 2022-04-29 南京港华能源投资发展有限公司第一分公司 Data analysis system and method for efficient central heating of cold and heat source machine room
CN114413324B (en) * 2022-02-22 2022-11-04 南京港华能源投资发展有限公司第一分公司 Efficient central heating system and method for cold and heat source machine room

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