CN104772319A - Heating biological system and method - Google Patents
Heating biological system and method Download PDFInfo
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- CN104772319A CN104772319A CN201510102910.5A CN201510102910A CN104772319A CN 104772319 A CN104772319 A CN 104772319A CN 201510102910 A CN201510102910 A CN 201510102910A CN 104772319 A CN104772319 A CN 104772319A
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Abstract
The invention disclosed is a heating biological system and method. The biological heating system at least comprises a low temperature tank and high temperature tank in adjacent arrangement. Each tank is provided with organic wastes, the volume of the low temperature tank is 3-10 times the volume of the high temperature tank; biological bacteria is placed in the tanks, wherein the biological bacteria is Bacillus subtilis, Bacillus licheniformis and / or actinomycete; a low temperature heat exchanger is arranged in the middle of the low temperature tank, and the low temperature heat exchanger is provided with a water inlet pipe and a water outlet pipe; a high temperature heat exchanger is arranged in the middle of the high temperature tank, and the high temperature heat exchanger is provided with a water inlet pipe and water outlet pipe; and the water outlet pipe of low temperature heat exchanger and the water inlet pipe of the high temperature heat exchanger are communicated with each other. The above system and the method make full use of domestic wastes (organic waste) which are unrecyclable, change waste to treasure, and benefit environmental protection and garbage disposal. A large number of high temperature hot water can be produced to meet the requirements of wide range heating.
Description
Technical field
The present invention relates to a kind of biological heating groove.
Background technology
Fire coal, electricity, fuel oil, combustion gas and geothermal heating system several traditional heating mode waste non-renewable resources, again serious environment pollution is generally adopted, the problems such as polluted underground water matter in order to overcome in prior art to warm oneself; Publication number CN 103968449 A Chinese patent proposes method and the device thereof that a kind of biofermentation adds heat exchange heating.It is joined in biological reaction tank by EM bacterium, and keep humidity between 35-45%; Make the organic materials such as rice husk or peanut shell biological bacteria under suitable humidity make it naturally generate heat to 65-75 DEG C by fermentation, the heat of generation is absorbed by heat exchanger again, exports to terminal use's heating.
Owing to using EM bacterium at high temperature can mortality, therefore in order to ensure that it is survived, its heating temp controls usually below 70 DEG C.Will certainly cause like this produce temperature can not be too high, fed distance can not be too far away, is usually only applicable to family and uses.
Further, what it used be rice husk, peanut shell, stalk carry out sending out this ferment, and these materials contain the compositions such as protein, are usually used to add in feed go, and therefore, price is higher.
Summary of the invention
For overcoming above-mentioned defect, the object of the present invention is to provide the biology heating groove that a kind of method is simple, cost is low, temperature is high.
For achieving the above object, biological heat-generating system of the present invention, at least comprises the cryostat, and high temperature groove that are disposed adjacent, and wherein, each groove is built with organic waste, and the volume of described cryostat, is 3-10 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides; Wherein,
In described groove, be placed with the biological bacteria of 1000-2000 kilogram in every 1 ten thousand stere organic waste, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium;
Also be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram;
In the middle part of described cryostat, be provided with cryogenic heat exchanger, described cryogenic heat exchanger is provided with water inlet pipe and outlet pipe; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; The outlet pipe of described cryogenic heat exchanger is connected with high-temperature heat-exchanging water inlet pipe.
Preferably, in described groove, biological corruption agent 200-400 kilogram in every 1 ten thousand stere organic waste, is also placed with.
Preferably, in described groove, the biological bacteria of following weight in every 1 ten thousand stere organic waste, is placed with: bacillus subtilis 500-700 kilogram bacillus licheniformis 500-700 kilogram radiation bacterium 200-300 kilogram.
For achieving the above object, biological heat-generating system of the present invention, comprises multiple cryostat, and more than one high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is more than 1 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides, wherein,
In described groove, be placed with the biological bacteria of 1000-2000 kilogram in every 1 ten thousand stere organic waste, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium;
Also be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram;
In the middle part of described each cryostat, be provided with cryogenic heat exchanger, described each cryogenic heat exchanger connects with series connection and/or parallel form and at least forms low temperature outfall sewer; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; Described low temperature outfall sewer is connected with high-temperature heat-exchanging water inlet pipe.
For achieving the above object, biological heat-generating system of the present invention, is characterized in that, comprises multiple cryostat, and more than one high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is more than 1 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides, wherein,
In described cryostat, be placed with the biological bacteria of 1000-2000 kilogram in every 1 ten thousand stere organic waste, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium; Also be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram;
Bacillus subtilis and the 600-1000 kilogram of probio of 1000-2000 kilogram is placed with in every 1 ten thousand stere organic waste in described high temperature groove;
In the middle part of described each cryostat, be provided with cryogenic heat exchanger, described each cryogenic heat exchanger connects with series connection and/or parallel form and at least forms low temperature outfall sewer; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; Described low temperature outfall sewer is connected with high-temperature heat-exchanging water inlet pipe.
Preferably, in described cryostat, and high temperature groove, biological corruption agent 200-400 kilogram in every 1 ten thousand stere organic waste, is also placed with.
For achieving the above object, biological heating method of the present invention, producing the heat needed for heat supply for utilizing biological bacteria to make organic refuse fermentation, it is characterized in that, in every 1 ten thousand stere organic waste, throw in profitable probliotics 600-1000 kilogram and 1000-2000 kilogram of biological bacteria; Wherein, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium.
Preferably, described biological bacteria is made up of following raw material bacterium: bacillus subtilis 500-700 kilogram, bacillus licheniformis 500-700 kilogram, radiation bacterium 200-300 kilogram.
Adopt said system and method to carry out biology heating, there is following effect:
1, take full advantage of the house refuse (organic waste) but grown on trees that cannot recycle, turn waste into wealth, be conducive to the process of environmental protection and rubbish, using electricity wisely, with coal etc.
2, all adopt house refuse, cost is low, instant effect, is conducive to the recycling of resource.
3, can a large amount of high-temperature-hot-waters be produced, meet the requirement that heats on a large scale.
4, utilize cryostat, to ferment fully, organic waste is made full use of; Utilize high temperature groove that heating can be provided temperature required, be conducive to using on a large scale.
Accompanying drawing explanation
Fig. 1 is biological heat-generating system structural representation of the present invention.
Fig. 2 is the schematic perspective view of heat-generating system biological shown in Fig. 1.
Detailed description of the invention
Below in conjunction with accompanying drawing, the present invention is further illustrated.
Biological heat-generating system of the present invention, at least comprises the cryostat, 1 and high temperature groove 2 that are disposed adjacent, and being disposed adjacent is to be conducive to pipeline transmission, in order to avoid except thermal loss; Wherein, each groove is built with organic waste 3, and the volume of described cryostat, is 3-10 times of high temperature groove volume; Wherein, in described groove, be placed with the biological bacteria of 1000-2000 kilogram weight in every 1 ten thousand stere organic waste, described biological bacteria is: bacillus subtilis, bacillus licheniformis and/or radiation bacterium; Be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram; Above-mentioned cryostat, conventionally controls its temperature and is positioned at less than 70 degree; Above-mentioned high temperature groove does not then carry out temperature control, and its temperature more than 90 degree, when finding that temperature is low, can need supplement biological bacteria or organic waste usually.
Described cryostat, and high temperature groove are provided with groove lid 11, cover at described groove and be provided with multiple bacterium liquid and add hand-hole 12; Organic waste charging aperture 13 is provided with in described cell body one or both sides;
In the middle part of cryostat, be provided with cryogenic heat exchanger 4, cryogenic heat exchanger is provided with water inlet pipe and outlet pipe; In the middle part of high temperature groove, be provided with high-temperature heat-exchanging 5, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; The outlet pipe of described cryogenic heat exchanger is connected with high-temperature heat-exchanging water inlet pipe.Wherein, be provided with cryogenic heat exchanger multilayer aluminum plastic pipe can be utilized to be coiled to form in the middle part of cryostat, composition multilayer or multi-group heat exchanger, to improve heat exchange efficiency, and cost is low, easy to make.
Shorten the rubbish corruption time to improve, in described groove, be also placed with biological corruption agent 200-400 kilogram in every 1 ten thousand stere organic waste, biological corruption agent also claims organic matter decomposing inoculant.
Biological heat-generating system of the present invention can also provide heating for large-scale community, and it can pass through multiple cryostat, and high temperature groove, and series connection and/or parallel form are connected to form, and are not repeating a bit.
Biological heating method of the present invention, produces the heat needed for heat supply for utilizing biological bacteria to make organic refuse fermentation, throwing in every 1 ten thousand stere organic waste has 1000-2000 kilogram of biological bacteria, and wherein said biological bacteria is made up of probio and biological bacteria; Wherein, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium.
Usually embodiment is described below
Embodiment 1
Biological heat-generating system of the present invention, comprises a cryostat, and a high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is 3 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Be provided with organic waste charging aperture in described cell body one or both sides, wherein, in cryostat, and high temperature groove, throw in bacillus subtilis 1000 kilograms of probios 1000 kilograms by every 1 ten thousand stere organic waste.
Embodiment 2
Biological heat-generating system of the present invention, comprises two cryostat,s and a high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is 2 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with, wherein, in cryostat, and high temperature groove, by throwing in bacillus subtilis 500 kilograms, bacillus licheniformis 500 kilograms of probios 500 kilograms in every 1 ten thousand stere organic waste in described cell body one or both sides.
Embodiment 3
Biological heat-generating system of the present invention, comprises a cryostat, and a high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is 5 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with, wherein, in cryostat, and high temperature groove, by throwing in radiation bacterium 500 kilograms of bacillus licheniformis 500 kilograms of probios 500 kilograms in every 1 ten thousand stere organic waste in described cell body one or both sides.
Embodiment 4
Biological heat-generating system of the present invention, comprises two cryostat,s and a high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is 3 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with, wherein, in cryostat, and high temperature groove in described cell body one or both sides, bacillus subtilis 800 kilograms is thrown in, bacillus licheniformis 400 kilograms, radiation bacterium 200 kilograms by every 1 ten thousand stere organic waste, probio 600 kilograms, biological corruption agent 200 kilograms.
Embodiment 5
Biological heat-generating system of the present invention, comprises multiple cryostat, and a high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is more than 1 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides, wherein,
Throw in by every 1 ten thousand stere organic waste in cryostat:
Bacillus licheniformis 1000 kilograms, radiation bacterium 200 kilograms; Probio 600 kilograms; Biological corruption agent 200 kilograms.
Throw in every 1 ten thousand stere organic waste in high temperature groove: bacillus subtilis 1000 kilograms and probio 600-1000 kilogram; Biological corruption agent 400 kilograms.
In the middle part of described each cryostat, be provided with cryogenic heat exchanger, described each cryogenic heat exchanger connects with series connection and/or parallel form and at least forms low temperature outfall sewer; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; Described low temperature outfall sewer is connected with high-temperature heat-exchanging water inlet pipe.
The present embodiment makes full use of the resistant to elevated temperatures feature of bacillus subtilis, is that master carries out fermentation heating to organic waste, thus improves the fermentation temperature in high temperature groove, to reach living needs in high temperature groove with bacillus subtilis.
Embodiment 6
Biological heat-generating system of the present invention, comprises multiple cryostat, and a high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is more than 1 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides, wherein,
Throw in by every 1 ten thousand stere organic waste in cryostat:
Bacillus licheniformis 500 kilograms, radiation bacterium 500 kilograms, bacillus subtilis 500 kilograms, probio 600 kilograms, biological corruption agent 200 kilograms
Throw in every 1 ten thousand stere organic waste in high temperature groove: bacillus subtilis 1000 kilograms and probio 600-1000 kilogram; Biological corruption agent 400 kilograms
In the middle part of described each cryostat, be provided with cryogenic heat exchanger, described each cryogenic heat exchanger connects with series connection and/or parallel form and at least forms low temperature outfall sewer; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; Described low temperature outfall sewer is connected with high-temperature heat-exchanging water inlet pipe.
Claims (8)
1. a biological heat-generating system, is characterized in that, at least comprises the cryostat, and high temperature groove that are disposed adjacent, and wherein, each groove is built with organic waste, and the volume of described cryostat, is 3-10 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides; Wherein,
In described groove, be placed with the biological bacteria of 1000-2000 kilogram in every 1 ten thousand stere organic waste, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium;
Also be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram;
In the middle part of described cryostat, be provided with cryogenic heat exchanger, described cryogenic heat exchanger is provided with water inlet pipe and outlet pipe; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; The outlet pipe of described cryogenic heat exchanger is connected with high-temperature heat-exchanging water inlet pipe.
2. biological heat-generating system as claimed in claim 1, is characterized in that, is also placed with biological corruption agent 200-400 kilogram in described groove in every 1 ten thousand stere organic waste.
3. the biological heat-generating system as described in claim as arbitrary in claim 1 or 2, it is characterized in that, in described groove, in every 1 ten thousand stere organic waste, be placed with the biological bacteria of following weight: bacillus subtilis 500-700 kilogram bacillus licheniformis 500-700 kilogram radiation bacterium 200-300 kilogram.
4. a biological heat-generating system, is characterized in that, comprises multiple cryostat, and more than one high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is more than 1 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides, wherein,
In described groove, be placed with the biological bacteria of 1000-2000 kilogram in every 1 ten thousand stere organic waste, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium;
Also be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram;
In the middle part of described each cryostat, be provided with cryogenic heat exchanger, described each cryogenic heat exchanger connects with series connection and/or parallel form and at least forms low temperature outfall sewer; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; Described low temperature outfall sewer is connected with high-temperature heat-exchanging water inlet pipe.
5. a biological heat-generating system, is characterized in that, comprises multiple cryostat, and more than one high temperature groove, and wherein, each groove is built with organic waste, and the volume of described cryostat, is more than 1 times of high temperature groove volume; Separated by thermal insulation wall between described cryostat, and high temperature groove, described cryostat, and high temperature groove are provided with groove lid, cover at described groove and be provided with multiple bacterium liquid and add hand-hole; Organic waste charging aperture is provided with in described cell body one or both sides, wherein, in described cryostat, be placed with the biological bacteria of 1000-2000 kilogram in every 1 ten thousand stere organic waste, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium; Also be placed with in every 1 ten thousand stere organic waste in described groove: probio 600-1000 kilogram;
Bacillus subtilis and the 600-1000 kilogram of probio of 1000-2000 kilogram is placed with in every 1 ten thousand stere organic waste in described high temperature groove;
In the middle part of described each cryostat, be provided with cryogenic heat exchanger, described each cryogenic heat exchanger connects with series connection and/or parallel form and at least forms low temperature outfall sewer; In the middle part of described high temperature groove, be provided with high-temperature heat-exchanging, described high-temperature heat-exchanging is provided with water inlet pipe and outlet pipe; Described low temperature outfall sewer is connected with high-temperature heat-exchanging water inlet pipe.
6. biological heat-generating system as claimed in claim 5, is characterized in that, is also placed with biological corruption agent 200-400 kilogram in described cryostat, and high temperature groove in every 1 ten thousand stere organic waste.
7. a biological heating method, producing the heat needed for heat supply, it is characterized in that for utilizing biological bacteria to make organic refuse fermentation, throws in profitable probliotics 600-1000 kilogram and 1000-2000 kilogram of biological bacteria in every 1 ten thousand stere organic waste; Wherein, described biological bacteria is bacillus subtilis, bacillus licheniformis and/or radiation bacterium.
8. biological heating method as claimed in claim 7, is characterized in that, described biological bacteria is made up of following raw material bacterium:
Bacillus subtilis 500-700 kilogram, bacillus licheniformis 500-700 kilogram, radiation bacterium 200-300 kilogram.
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Application publication date: 20150715 |