CN2782662Y - Circular shape ultraviolet lamp tube water purifier - Google Patents

Abstract

The utility model relates to a water conditioner with annular ultraviolet lamp tubes. At least one annular ultraviolet lamp tube surrounds the outside of a transparent silica glass water tube; the annular ultraviolet lamp tube can also be formed by arranging a plurality of straight ultraviolet lamp tubes in an annularity along the outer side of the circumferential direction of the silica glass tube. The utility model can adopt the transparent silica glass water tube, or adopt the water tubes formed by hermetically connecting a section of the transparent silica glass to the middle of a the water tube of which both ends are made of traditional materials and surrounding the transparent silica glass with the annular ultraviolet lamp tube. A reflecting shade is arranged at the outers side of the annular ultraviolet lamp tube so as to completely reflect ultraviolet rays emitted by the ultraviolet lamp tube to the inside of the silica glass tube.

Description

A kind of water purifier with annular ultraviolet lamp tube

Technical field

The utility model relates to a kind of water treatment device, specifically, relates to a kind of water purifier that utilizes ultraviolet ray to carry out water treatment.The utility model can be used in drinking water purification system and the sewage sterilization system.

Background technology

Ultraviolet ray (UV) is meant the luminous energy of wavelength region at 100～400nm, and it is in spectrum between X ray and the visible light.Most of uv sterilisation equipment use short wavelength's part of UV spectrum, and this part is called UV-C, and wavelength is between 200～280nm.

Ultraviolet ray can be killed range of pathogen, and as bacterium, virus and protobiont, these pathogenic agent can cause as various diseases such as amebic dysentery, cholera, poliomyelitis and yellow jack.Uv-radiation works by the chemical bonding structure that destroys dna molecular, and it influences normal dna replication dna, makes organism death or inactivation.At present, the ultraviolet water sterilization is used for tap water, sewage and culture fishery, and the progress of ultraviolet technology in these industries determined that some influence the parameter of UV disinfection system operating performance.

The UV-C technology is regarded as one of four kinds of approval methods of water sterilization by Environmental Protection Agency (EPA), and because the advantage aspect expense and efficient, UV-C (the UV-C effect almost is instantaneous, any chemical residual can not arranged in water) is more even better than other three kinds of methods (chlorine, ozone and distillation).At present, Environmental Protection Agency (EPA) and U.S. food and drug administration (FDA) assert that all the UV-C radiation is a kind of safe, water treatment method efficiently.This method is quick, does not change the pH value and the taste of water, and does not use excessive danger, is a kind of microorganism killing method non-chemically, can not produce poisonous byproduct.Simultaneously, UV-C also is the water sterilization method of World Health Organization's approval.

The degree of killing of microorganism is the common function of exposure duration and yield of radiation.The product (being ultraviolet dosage) of supposing exposure duration and yield of radiation remains unchanged, and high-intensity radiation of short period of time is identical with long-time low intensive radiating effect.UV intensity and exposure duration are depended on the geometrical shape and the flow dynamic characteristic of ultraviolet system.The minimum uv dosage design that the ultraviolet system is required according to the killing microorganisms that water obtained, dose unit is generally μ Ws/cm ²The radiation dose of kill bacteria is 3～30mJ/cm ², kill virus needs 30～100mJ/cm ²In addition, nearest studies show that, uv-radiation also has effect to Giardia and the Cryptosporidium that causes pathology in the body, as long as make it be exposed to tens of mJ/cm ²Dosage just can remove a hidden danger down.

At present traditional uv steriliser as shown in Figure 1.Straight type ultraviolet lamp tube a is positioned at water pipe b center, and water flows through an annular region.The ultraviolet lamp tube radius is R _B(m), the outer tube radius is R _P(m), sterilizer length is L (m), and the volumetric flow rate of water is G (m ³/ s), power of lamp tube is P _B(m).During flowing water process water pipe, by a ultra violet lamp.So just the bigger power of needs reaches the effective processing to water.Above-mentioned design has two defectives.The first since water to the absorption of light, uitraviolet intensity increases with the distance on distance lamp surface and successively decreases, ultraviolet dosage distributed pole in such system is inhomogeneous, away from the place of fluorescent tube may because of dosage is too low can't kill microorganisms; It two is that when the annularly flow area increased with radius, uitraviolet intensity successively decreased.As a result, the distribution of dose gradient in the pipe is very big, need use very high power just can reach the lowest dose level that the tube wall place needs at tube hub, and increase the power of ultraviolet lamp or the length of ultraviolet lamp tube, all can increase the volume and the energy expenditure of water treatment device.

The utility model content

The purpose of this utility model is to provide a kind of water purifier that adopts annular ultraviolet lamp tube.

For achieving the above object, the water purifier with annular ultraviolet lamp tube that the utility model provides, its structure is:

At least one annular ultraviolet lamp tube is arranged on silica glass water pipe outside around ground.

Annular ultraviolet lamp tube wherein can be positioned to ring-like along quartz glass tube by some straight type ultraviolet lamp tubes in week laterally.

The utility model can be used for the household drinking water sterilization, and water field or other water facilities also can be used for sewage treatment facility.

The water purifier that the utility model provides can produce a stronger UV intensity field in whole water flow passage, make water receive high-intensity, uniform UV-light dosage.

Compare with conventional art, the utility model has the advantages that:

1) in the conventional art, fluorescent tube, needs to strengthen the power of ultraviolet lamp or reduces flow velocity if reach higher dosage in the central authorities of runner.The utility model need not strengthen ultraviolet lamp power or reduce flow velocity, so can conserve energy or improve treatment capacity in the unit time.

2) ultraviolet lamp of the present utility model is placed in outside the water pipe, and in the time of can guaranteeing just in case ultraviolet lamp breaks (have an accident etc.), the mercury in the ultraviolet lamp can not pollute the water in the water pipe.

3) owing to adopted ring shaped lamp, the total length of system will shorten greatly, can save installing space.

Description of drawings

Fig. 1 is the synoptic diagram of water treatment device in the background technology.

Fig. 2 is the synoptic diagram of the utility model water purifier, and wherein Fig. 2 a is depicted as annular ultraviolet lamp tube, and its water pipe is that transparency silica glass is made; Fig. 2 b is depicted as the annular ultraviolet lamp tube of being made up of straight type ultraviolet lamp tube, and its water pipe water pipe that to be two ends made by traditional material is clipped in the middle one section transparent quartz glass tube sealing and forms the one water pipe.

Fig. 3 sets up synoptic diagram for the coordinate of reflection shield mathematical model of the present invention.

Fig. 4 is the three-dimensional plot of reflection shield of the present invention, a) is the reflection shield overall three-dimensional view wherein; B) be the reflection shield longitudinal section; C) be the reflection shield sectional elevation.

Fig. 5 is the profile synoptic diagram of reflection shield of the present invention.

Fig. 6 is the uv energy distribution schematic diagram of annular ultraviolet lamp tube of the present invention in water pipe.

Fig. 7 is G=0.0061m for discharge in the water pipe of the present invention ³/ s (100GPM), water purifier length are that L=0.1m, water purifier radius are R _BWhen the ultraviolet output rating of=0.3m, fluorescent tube is respectively 20W, 30W and 50W, ultraviolet intensity distribution synoptic diagram in the water purifier.

Fig. 8 is that the performance of apparatus of the present invention and background art device compares.

Embodiment

See also Fig. 2, be water purifier structural representation of the present utility model.

As can be seen, water purifier of the present utility model is looped around the outside of silica glass water pipe 2 by at least one annular ultraviolet lamp tube 1 from Fig. 2 a.Concrete installation quantity as for annular ultraviolet lamp tube 1 can be decided as required.

See also Fig. 2 b, the water pipe 2 ' that water pipe of the present utility model can also adopt traditional material to make, at annular ultraviolet lamp tube 1 around the part one section silica glass water pipe 2 that is tightly connected.According to the water pipe that the utility model is made, it is that water pipe that traditional material makes is clipped in the middle one section transparent quartz glass tube sealing and forms the one aquaporin that reality has formed two ends.Annular ultraviolet lamp tube is looped around the quartz glass tube place.

Again in conjunction with Fig. 2 b, annular ultraviolet lamp tube 1 of the present utility model can also be week laterally to be positioned to ring-like along quartz glass tube 2 some straight type ultraviolet lamp tubes 1 '.

Because the utility model has adopted ring shaped lamp, the total length of system will shorten greatly, can save installing space.Ultraviolet lamp tube of the present utility model should be as much as possible near quartz glass tube, and maximum spacing can not be above 10 centimetres.For improving purifying water effect of the present utility model, ultraviolet reflection shield can also be settled in the outside of above-mentioned two kinds of ultraviolet lamp tubes, and this reflection shield is inboard to be ultraviolet reflectance coating.The ultraviolet ray reflection shield can guarantee that ultraviolet ray do not leak fully, and easy accessibility.

About ultraviolet reflection shield, by as can be known to the analysis of annular UV intensity field, a uv energy part of sending from ultraviolet lamp tube directly shines flow through the reactor waterborne through quartz glass tube, and another part is waterborne by just shining after the reflection shield reflection.Under design conditions, reflected energy accounts for the major part of the ultraviolet total energy that fluorescent tube sends

$\frac{180+\mathrm{arctg}\frac{0.9}{5}}{360}=55.6\%$

Therefore, the ultraviolet reflection shield that the utility model provides designs according to the following stated, to obtain the ultraviolet reflection shield of the sterilizing rate under the design discharge.

If luminous energy is at the surface of the light tube uniform distribution, light is after fluorescent tube radially sends, by radially inciding in the reactor along quartz glass tube after the refraction of reflection shield.Hence one can see that, and this reflection shield is roughly one and takes turns fetalism.

Because the UV intensity field is symmetrically distributed at the annular lamp tube two ends, reflection shield also should be symmetric about the axis of fluorescent tube, so can simplify processing in mathematical model, only considers that half gets final product.

Arbitrary the bus that makes quartz glass tube is the x axle, and the fluorescent tube center on the corresponding same section is

O ₁(0, m) [establish m=d+r _Uv],

Light is radially handed over 1 P on the reflection shield after the outgoing along fluorescent tube, and (x y), reflexes on the quartz glass tube after reaching P at once, that is, reflection ray is vertical with the quartz glass tube wall.

The coordinate of setting up reflection shield according to physical model as shown in Figure 3.Suppose to have a unknown curve at first quartile, (x y) makes the tangent line PC of this curve, crosses some P and prolongs and hand over x axle and some B making normal to a curve by any point P on the curve; Cross some P and make RA  x axle, intersection point is A; Connect O ₁P always has ∠ O ₁PB=∠ BPA sets up, and promptly BP is ∠ O ₁The angular bisector of PA.If angle θ is O ₁The forward angle of P and x axle, establishing angle γ is the forward angle of CP and x axle.By analysis as can be known $\mathrm{\γ}=\frac{\mathrm{\θ}}{2}-\frac{\mathrm{\π}}{4}$ Relation set up all the time, and $\mathrm{\γ}\∈[-\frac{5\mathrm{\π}}{18},0].$

If curvilinear equation is y=f (x), then the mathematical model of reflection shield can be set up as follows:

f′(x)＝tg(π-|γ|)＝-tg|γ|＝tgγ

f′(x＝0)＝0

$f(x=\frac{L}{2})=0$

Wherein,

$\mathrm{tg\γ}=\mathrm{tg}(\frac{\mathrm{\θ}}{2}-\frac{\mathrm{\π}}{4})$

∵ $\mathrm{tg}(\mathrm{\α}-\mathrm{\β})=\frac{\mathrm{tg\α}-\mathrm{tg\β}}{1+\mathrm{tg\αtg\β}}$

∴ $\mathrm{tg\γ}=\frac{\mathrm{tg}\frac{\mathrm{\θ}}{2}-1}{1+\mathrm{tg}\frac{\mathrm{\θ}}{2}}$

∵ again $\mathrm{tg}\frac{\mathrm{\α}}{2}=\frac{\sin \mathrm{\α}}{1+\cos \mathrm{\α}}$

∴ $\mathrm{tg\γ}=\frac{\frac{\sin \mathrm{\θ}}{1+\cos \mathrm{\θ}}-1}{1+\frac{\sin \mathrm{\θ}}{1+\cos \mathrm{\θ}}}=\frac{\sin \mathrm{\θ}-\cos \mathrm{\θ}-1}{\sin \mathrm{\θ}+\cos \mathrm{\θ}+1}$

As shown in Figure 3 $\sin \mathrm{\θ}=\frac{y-m}{\sqrt{{(y-m)}^2+x^2}},$ $\cos \mathrm{\θ}=\frac{x}{\sqrt{{(y-m)}^2+x^2}},$ Obtain after bringing following formula and arrangement into:

$\mathrm{tg\γ}=\frac{y-m-x-\sqrt{{(y-m)}^2+x^2}}{y-m+x+\sqrt{{(y-m)}^2+x^2}}$

Bring into the mathematical model net result that can obtain reflection shield behind the top equation as shown in the formula:

$f^{\′}\left(x\right)=\frac{y-m-x-\sqrt{{(y-m)}^2+x^2}}{y-m+x+\sqrt{{(y-m)}^2+x^2}}$

$\mathrm{BC}:f^{\′}(x=0)=0;f(x=\frac{L}{2})=0$

According to above-mentioned analysis, can depict the basic configuration of the utility model reflection shield 3-D view, shown in Fig. 4 a, b, c.Obtain a numerical value file that comprises 51 points thus, when other geometric conditions were constant, the processing of reflection shield can be carried out according to this numerical value document result.The numerical value file is referring to table 1.

Table 1 reflection shield CAD numerical point (unit: cm)

N	x	y	n	x	Y
						0	0	3.679	26	2.6	2.916
1	0.1	3.679	27	2.7	2.847
						2	0.2	3.679	28	2.8	2.774
3	0.3	3.679	29	2.9	2.698
						4	0.4	3.679	30	3	2.618
5	0.5	3.678	31	3.1	2.534
						6	0.6	3.674	32	3.2	2.447
7	0.7	3.666	33	3.3	2.355
						8	0.8	3.653	34	3.4	2.26
9	0.9	3.637	35	3.5	2.16
						10	1	3.617	36	3.6	2.056
11	1.1	3.595	37	3.7	1.947
						12	1.2	3.57	38	3.8	1.833
13	1.3	3.541	39	3.9	1.714
						14	1.4	3.511	40	4	1.591
15	1.5	3.477	41	4.1	1.461
						16	1.6	3.44	42	4.2	1.326
17	1.7	3.395	43	4.3	1.185
						18	1.8	3.353	44	4.4	1.038
19	1.9	3.315	45	4.5	0.884
						20	2	3.266	46	4.6	0.723
21	2.1	3.216	47	4.7	0.555
						22	2.2	3.162	48	4.8	0.378
23	2.3	3.105	49	4.9	0.194

24	2.4	3.046	50	5	0
						25	2.5	2.983

According to above-mentioned analysis, its profile cross section of reflection shield of the present utility model as shown in Figure 5.

About the kind and the installation method of reflector is a known technology, so the utility model is not described in detail, and do not recommend accompanying drawing yet.

Water purifier of the present utility model, under the ultraviolet lamp tube condition of using with traditional water treatment unit equal-wattage, because the reducing of area, the uitraviolet intensity of tube hub will be higher than the intensity (as shown in Figure 6) in the outside along radial direction.This is very helpful to reducing energy expenditure.The utility model can save energy 20～80% than traditional water treatment unit.Another one advantage of the present utility model in addition is that ultraviolet lamp is placed in outside the water pipe, and in the time of can guaranteeing just in case ultraviolet lamp breaks (have an accident etc.), the mercury in the ultraviolet lamp can not pollute the water in the water pipe.

By calculating as can be known, when the diameter of water purifier during greater than 32 centimetres, the utility model is compared with at present traditional water treatment device, and maximum fractional energy savings can reach 80%, concrete physical model and being calculated as follows:

If the ultraviolet ray of sending from ultraviolet lamp tube is all absorbed by water, the uitraviolet intensity at the surface of the light tube place should be:

$I_0=\frac{P_B}{2\mathrm{\π}{R}_{B}L}\·\·\·\left(1\right)$

Wherein the fluorescent tube radius is R _B(m), water purifier length is L (m), and the ultraviolet power that ultraviolet lamp tube sends is P _B(W).For water purifier structure shown in Figure 2, ultraviolet intensity distribution is:

$I=\frac{P_B}{2\mathrm{\πrL}}{e}^{-2.3(R_B-r)}\·\·\·\left(2\right)$

Ultraviolet intensity distribution when Fig. 7 is 0.3 meter for the water purifier radius.As can be seen from Figure 7, the minimum value of ultraviolet intensity is the surface at ultraviolet lamp tube, and maximum value appears at the center of water purifier.The distribution of ultraviolet irradiation value D is as follows

$D=\frac{P_B{R}_B^2}{2\mathrm{rG}}{e}^{-2.3(R_B-r)}\·\·\·\left(3\right)$

Wherein the volumetric flow rate of water is G (m ³/ s).Fig. 6 is G=0.0061m for discharge ³/ s (100GPM), water purifier length are that L=0.1m, water purifier radius are R _BWhen the ultraviolet output rating of=0.3m, fluorescent tube is respectively 20W, 30W and 50W, the distribution of water purifier internal irradiation value D.From result shown in Figure 6 as can be seen, the ultraviolet output rating of fluorescent tube only is 20W, and the interior ultraviolet irradiation minimum value of water purifier is the value of being above standard.Therefore the ultraviolet output rating of fluorescent tube is:

$P_B\≥\frac{2G{D}_c}{R_B}\·\·\·\left(4\right)$

Fig. 8 is that the utility model and traditional water treatment unit performance compare.As can be seen from the figure, fractional energy savings of the present utility model can reach 80%.

Claims (5)

1. a water purifier that adopts annular ultraviolet lamp tube is characterized in that, at least one annular ultraviolet lamp tube is arranged on transparency silica glass water pipe outside around ground.

2. the water purifier of claim 1 is characterized in that, described annular ultraviolet lamp tube is positioned to ring-like by some straight type ultraviolet lamp tubes along transparent quartz glass tube in week laterally.

3. claim 1 or 2 water purifier is characterized in that the spacing of described ultraviolet lamp tube and transparent quartz glass tube is 0-10 centimetre.

4. claim 1 or 2 water purifier is characterized in that the outside of described ultraviolet lamp tube is mounted with metallic bowl, and this reflector is inboard to be ultraviolet reflectance coating, the shape coincidence formula of this reflection shield

$f\left(x\right)=\frac{y-m-x-\sqrt{{(y-m)}^2+x^2}}{y-m+x+\sqrt{{(y-m)}^2+x^2}}$

$\mathrm{BC}:f(x=0)=0;f(x=\frac{L}{2})=0.$

5. the water purifier of claim 1 is characterized in that, described water pipe is that the water pipe that make with traditional material at two ends seals the one water pipe that is clipped in the middle and forms with one section transparent quartz glass tube, and annular ultraviolet lamp tube is looped around the quartz glass tube place.

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