CN102084854B - Fishing lamp - Google Patents

Abstract

Conventional fishing lamp has the problems that variation of illumination intensity due to shaking of a boat may result in that inkfish, pacific sauries, sardines and barracuda are unlikely to gather or likely to depart again after gathering. The fishing lamp 10 is characterized in comprising a section including a grading mode having a first grading peak P1 and a second grading peak P2 different from each other, and the first grading peak P1 is smaller than the second grading peak P2.

Description

Poly-fish lamp

Technical field

The present invention relates to a kind of poly-fish lamp in order to assemble inkfish, saury, sardine, Scad fish etc.

Background technology

Used the poly-fish lamp of the lamps such as incandescent lamp, Halogen lamp LED, metal halid lamp there are the following problems in the past: cause fuel oil to consume in a large number, because discharging a large amount of CO due to light utilization ratio difference ₂and increase environmental pressure.In addition, there are the following problems: irradiate to all directions and also can confirm that the too dazzling light of this degree becomes light pollution from moonlet, bag light with violet rays produces baneful influence to human body.In this case, a kind of LED (light-emittingdiode, light emitting diode) that uses is proposed in recent years as the poly-fish lamp of light source.

Such as, in patent document 1, describe following content: use two panels LED flat light source, be combined into right side flat light source that sea on the right side of ship is irradiated and to the left side flat light source that sea on the left of ship is irradiated, can effectively irradiate sea whereby.

[conventional art document]

[patent document]

[patent document 1] Japanese Patent Laid-Open 2003-134967

Summary of the invention

[inventing problem to be solved]

But the poly-fish lamp recorded in patent document 1 only makes LED light effectively be irradiated to sea, mainly to improve for the purpose of light utilization ratio, be not conceived to because hull rocks the change of the marine Illumination Distribution caused.

That is, there are the following problems for poly-fish lamp in the past: cause marine Illumination Distribution to change because hull rocks, the catches such as inkfish, saury, sardine, Scad fish are not easily assembled, or the catches assembled and come leaves again.

[technological means of dealing with problems]

Poly-fish lamp of the present invention is arranged on hull, irradiates, it is characterized in that sea:

A plane orthogonal with described sea has comprise the 1st luminous intensity distribution peak value, with the luminous intensity distribution pattern of the 2nd luminous intensity distribution peak value, described 1st luminous intensity distribution peak value is in below horizontal under described hull is without the state of rocking, and described 2nd luminous intensity distribution peak value is in more than level.

The of the present invention poly-fish lamp formed in the manner comprises the 1st luminous intensity distribution peak value and the 2nd luminous intensity distribution peak value in luminous intensity distribution pattern, so within the scope of the maximum roll angle of the described hull centered by luminous intensity distribution central angle, the change of relative intensity can be reduced, even if when described hull rocks in maximum roll angle, the change of the distant place illumination away from hull also can be reduced.

And in poly-fish lamp of the present invention, preferably the intensity of described 1st luminous intensity distribution peak value is less than the intensity of described 2nd luminous intensity distribution peak value, can reduce the illumination change near hull whereby.

The preferably standby LED as light source of poly-fish light fixture and the distribution controls component that controls from the luminous intensity distribution of the light of described LED, and distribution controls component to comprise the distribution controls of the light from LED in the 1st distribution controls region of the 1st luminous intensity distribution peak value side, by the distribution controls of the light from LED in the 2nd distribution controls region of the 2nd luminous intensity distribution peak value side and the 3rd distribution controls region between the 1st distribution controls region and the 2nd distribution controls region.Now, 1st luminous intensity distribution peak value is repeated by the light of the 1st distribution controls Region control and the light part of the 3rd distribution controls Region control and formed, and the 2nd luminous intensity distribution peak value is repeated by the light of the 2nd distribution controls Region control and the light part of the 3rd distribution controls Region control and formed.

Under a cross section of poly-fish lamp is looked, preferably distribution controls component possesses multiple protuberance in the 1st distribution controls region, possesses multiple protuberance in the 2nd distribution controls region.

[effect of invention]

According to the present invention, can control, because hull rocks the change of the marine Illumination Distribution caused, therefore can realize the poly-fish lamp that poly-fish ability improves further.

Accompanying drawing explanation

Fig. 1 (a) is the perspective view of the poly-fish lamp of embodiment 1.

Fig. 1 (b) is the sectional view of the poly-fish lamp of embodiment 1.

Fig. 2 is the luminous intensity distribution striograph of the poly-fish lamp of embodiment 1.

Fig. 3 (a) is the luminous intensity distribution striograph that the poly-fish lamp of embodiment 1 irradiates from hull.

Fig. 3 (b) is the luminous intensity distribution striograph that the poly-fish lamp of embodiment 1 irradiates from hull.

Fig. 3 (c) is the luminous intensity distribution striograph that the poly-fish lamp of embodiment 1 irradiates from hull.

Fig. 4 represents the figure of the poly-fish lamp of embodiment 1 in the Illumination Distribution of marine irradiation.

Fig. 5 is the enlarged drawing near the LED of Fig. 1 (b).

Fig. 6 is the luminous intensity distribution striograph of Fig. 5.

Fig. 7 is the amplification sectional view near the LED of the poly-fish lamp of embodiment 2.

Fig. 8 represents by the 1st light distribution characteristic d1 of the 1st distribution controls region luminous intensity distribution, the 2nd light distribution characteristic d2 by the 2nd distribution controls region luminous intensity distribution, the 3rd light distribution characteristic d3 by the 3rd distribution controls region luminous intensity distribution and the chart by the light distribution characteristic td of poly-fish lamp entirety overlapping for described light distribution characteristic.

Fig. 9 (1), (2) to represent at hull without under the state of rocking, and light distribution characteristic irradiates the chart of the angle of the distant place datum mark P away from hull.

Figure 10 (1)-(8), under representing the state of rocking for-5 ° ,-10 ° ,-15 ° ,-20 ° at hull, light distribution characteristic irradiate the chart of the angle of the distant place datum mark P away from hull.

Figure 11 (1)-(8), under representing the state of rocking for+5 ° ,+10 ° ,+15 ° ,+20 ° at hull, light distribution characteristic irradiate the chart of the angle of the distant place datum mark P away from hull.

Figure 12 (1) ~ (3) are under the state representing that the poly-fish lamp of comparative example rocks for ± 0 ° ,-20 ° ,+20 ° at hull, on light distribution characteristic, irradiate the chart of the angle of the distant place datum mark P away from hull respectively, Figure 12 (4) represents the figure of the poly-fish lamp of comparative example in marine Illumination Distribution.

[explanation of symbol]

10 poly-fish lamps

11 substrates

12 LED

13 frameworks

14 distribution controls components

P1, P2 light

Embodiment

Below, one side illustrates with reference to graphic one side and is used for implementing form of the present invention.But the form shown below illustration just for the technology of the present invention thought being specialized, following content is not limited the present invention.

(embodiment 1)

Fig. 1 represents the poly-fish lamp 10 of this embodiment.Fig. 1 (a) is perspective view, and Fig. 1 (b) is the X-X sectional view that a cross section of Fig. 1 (a) is looked.Poly-fish lamp 10 possesses substrate 11, configuration on the substrate 11 and as the LED12 of light source, the framework 13 holding substrate 11 and the distribution controls component 14 controlled from the luminous intensity distribution of the light of LED12.Distribution controls component 14 utilizes screw etc. to be fixed in framework 13, but do not illustrate especially herein.

Fig. 2 represents the luminous intensity distribution pattern (left and right directions of Fig. 1 (b) corresponds to the left and right directions of Fig. 2) of the poly-fish lamp 10 in Fig. 1 (b) that a cross section is looked.In fig. 2, transverse axis represents angle, and the longitudinal axis represents relative luminous strength ratio (relative intensity).The luminous intensity distribution pattern of poly-fish lamp 10 a cross section depending under comprise the 1st different each other luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2 (between the 1st luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2 of maximum of maximum, there is minimum).Specifically, when poly-fish lamp 10 is arranged on hull, under hull is without the state of rocking, the 2nd luminous intensity distribution peak value above the 1st luminous intensity distribution peak value of horizontal direction (be parallel direction relative to sea) below and horizontal direction is comprised.Be configured to the 1st luminous intensity distribution peak value P1 and be less than the 2nd luminous intensity distribution peak value P2.

Whereby, even if hull rocks, also can irradiate (light can be made to arrive the marine of a hull distant place) the sea in a hull distant place all the time, thus effectively can suppress marine Illumination Distribution change.Therefore, it is possible to alleviate because of the problem that the change of marine Illumination Distribution causes catches not easily to be assembled or the catches assembling and come leaves and so on again.

The luminous intensity distribution pattern of poly-fish lamp 10 changes continuously.In fig. 2, from near-60 degree, relative intensity rises from 0, maximum (the 1st luminous intensity distribution peak value P1) is reached near-20 degree, minimum is reached near-5 degree, and maximum (the 2nd luminous intensity distribution peak value P2) is reached near+20 degree, near+60 degree, relative intensity drops to 0 afterwards.By by luminous intensity distribution Schema control at ± 60 degree, and realize except there is described effect, light utilization ratio also can not be impaired luminous intensity distribution pattern.But, luminous intensity distribution pattern of the present invention is not limited in the scope of roughly ± 60 degree, according to hull roll angle or the situation that arranges (arranging angle) of poly-fish lamp of supposition, such as ± 80 degree or ± 70 degree can be set to, also can make-side angle degree and+side angle degree is different.

Below, according to Fig. 3, the Illumination Distribution change utilizing formation of the present invention how can suppress marine is described.

Fig. 3 is the luminous intensity distribution striograph irradiated from the hull carrying poly-fish lamp 10.Fig. 3 (a) is the luminous intensity distribution striograph of hull without the state of rocking, Fig. 3 (b) is the luminous intensity distribution striograph of the state of hull inclination-20 degree (graphic middle left side), and Fig. 3 (c) is the luminous intensity distribution striograph of the state of hull inclination+20 degree (graphic middle right side).For the ease of understanding, the light of the 1st luminous intensity distribution peak value P1 corresponding to Fig. 2 is set to P1, the light of the 2nd luminous intensity distribution peak value P2 corresponding to Fig. 2 is set to P2 (P1 and P2 represents with solid line, and other are only represented by dotted lines).

Fig. 4 represents the marine Illumination Distribution in Fig. 3 (a) ~ (c) situation.The longitudinal axis represents the depth of water, and transverse axis represents the distance leaving hull.Herein, the Illumination Distribution of hull without the state of rocking (Fig. 3 (a)) is represented with solid line (a), represent the Illumination Distribution of the states (Fig. 3 (b)) of hull inclination-20 degree with dotted line (b), represent the Illumination Distribution of the states (Fig. 3 (c)) of hull inclination+20 degree with dotted line (c).Herein for the ease of understanding, also the light of the 1st luminous intensity distribution peak value P1 corresponding to Fig. 2 is set to P1, the light of the 2nd luminous intensity distribution peak value P2 corresponding to Fig. 2 is set to P2.

First, in this embodiment, as shown in Figure 4, a distant place (such as the place of distance more than hull 50m) marine illumination does not change.This has position a long way off to possess the light distribution characteristic of two peak value P1 and P2 by the poly-fish light fixture of this embodiment and realizes.

Such as, in this embodiment, suppose hull maximum inclination ± 20 °, if hull is tilted in ± 20 ° within the scope of, as shown in Fig. 9 ~ Figure 11, be not less than the mode of 0.7 with the relative intensity of the light irradiating the sea of the datum mark P in a hull distant place, setting comprises the interval of two peak value P1 and P2 and the light distribution characteristic of its intensity.

Relative to this, such as have in the poly-fish lamp of a peak value such as shown in Figure 12 (1) ~ (3), as shown in figure 12, when hull maximum inclination ± 20 °, the relative intensity of irradiating the light on the sea of the datum mark P in a hull distant place drops to the degree of 0.6 or 0.5.

Therefore, have in the poly-fish lamp of a peak value such as shown in Figure 12 (1) ~ (3), as shown in Figure 12 (4), when hull maximum inclination ± 20 °, the relative intensity of irradiating the light on the sea of the datum mark P in a hull distant place declines to a great extent.

In addition, in the chart of Figure 12 (4), solid line a represents the Illumination Distribution relative to the distance away from the hull without heeling condition, dotted line b represents the Illumination Distribution relative to the distance away from hull during inclination-20 °, and dotted line c represents the Illumination Distribution relative to the distance away from hull during inclination+20 °.

And the light distribution characteristic with the poly-fish lamp of the comparative example of a peak value as shown in Figure 12 (1) ~ (3), can by pulling down distribution controls component 14 from the poly-fish lamp of this embodiment and obtaining.

Below, the poly-fish lamp of this embodiment is described in detail.

Such as, in this embodiment, at hull without under the state of rocking, the 1st luminous intensity distribution peak value P1 is the below controlling in the horizontal direction (direction parallel with sea), and the 2nd luminous intensity distribution peak value P2 is the top (Fig. 3 (a)) controlled in the horizontal direction.Whereby, at hull without under the state of rocking, utilize the illumination of the 1st luminous intensity distribution peak value P1 to penetrate sea near hull, utilize the illumination between the 1st luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2 to penetrate the sea in a hull distant place.Now, marine Illumination Distribution is as shown in the solid line (a) of Fig. 4.

Now, even if the light irradiated between the 1st luminous intensity distribution peak value P1 on sea of the datum mark P in a hull distant place and the 2nd luminous intensity distribution peak value P2 be minimum, the relative intensity (reference Fig. 9 (1)) of higher more than 0.7 also can be had.

In addition ,-20 degree (on the left of Fig. 3) if hull tilts, then the sea near closer to hull is penetrated in the illumination of the 1st luminous intensity distribution peak value P 1, and the sea (Fig. 3 (b)) in a hull distant place is penetrated in the illumination of the 2nd luminous intensity distribution peak value P2.Whereby, even if under the state tilted as Fig. 3 (b) at hull, the light of the 2nd luminous intensity distribution peak value P2 also can be utilized to irradiate light to the sea in a hull distant place.Now, marine Illumination Distribution is as shown in the dotted line (b) of Fig. 4.

Now, the light on sea irradiating the datum mark P in a hull distant place has the relative intensity (with reference to Figure 10 (7)) of higher than the 2nd peak value about 0.8.

In addition ,+20 degree (on the right side of Fig. 3) if hull tilts, then the sea in a hull distant place is penetrated in the illumination of the 1st luminous intensity distribution peak value P1, and the light of the 2nd luminous intensity distribution peak value P2 irradiates more overhead compared with Fig. 3 (a) and (b).Whereby, even if under the state tilted as Fig. 3 (c) at hull, the light of the 1st luminous intensity distribution peak value P1 also can be utilized to irradiate light to the sea in a hull distant place.Now, marine Illumination Distribution is as shown in the dotted line (c) of Fig. 4.

Now, irradiate the light only roughly with the 1st peak value on sea of the datum mark P in a hull distant place, there is the relative intensity (with reference to Figure 11 (7)) of higher about 0.8.

As shown in Figure 4, the change of the marine Illumination Distribution away from hull tilting to cause due to hull can suppress in Min. by poly-fish lamp of the present invention.That is, even if under the state of hull inclination (dotted line (b) of Fig. 4, dotted line (c)), the sea in a hull distant place also can be light shone all the time, and the Illumination Distribution in a distant place can be made roughly fixing.In addition, near hull, also make the 1st luminous intensity distribution peak value P1 be less than the 2nd luminous intensity distribution peak value P2, the change of marine Illumination Distribution can be suppressed in Min. whereby.

This is because the intensity of light and square being inversely proportional to of distance leaving hull.That is, in the region in a hull distant place, the depth of water not easily because of the difference in size of the 1st luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2, light being arrived produces poor (in arbitrary situation of Fig. 4 (a) ~ (c), under leaving the distance of hull 100m, light arrives the marine of about 10m).Near hull, make the 1st luminous intensity distribution peak value P1 be less than the 2nd luminous intensity distribution peak value P2, compared with situation identical with both sizes whereby, to effectively suppress the change of Illumination Distribution (intensity of light and square being inversely proportional to of distance leaving hull, the size of therefore small near hull luminous intensity distribution peak value is poor, can produce considerable influence to Illumination Distribution).

In addition, more than illustrate be about hull without when tilting with during inclination ± 20 ° away from hull marine, with hull near marine Illumination Distribution, Figure 10 (1) ~ (6) and Figure 11 (1) ~ (6) represent when hull inclination ± 5 °, ± 10 °, ± 15 ° time irradiation distant place datum mark P the relative intensity of light.

Below, the formation of the poly-fish lamp of this embodiment is described.

Fig. 5 represents the enlarged drawing (not illustrating framework 13 in Figure 5) near a LED of Fig. 1 (b).Configure LED12 on the substrate 11, and subtend is provided with distribution controls component 14 in LED12.Distribution controls component 14 to comprise the distribution controls of the light from LED12 in the 1st distribution controls region of the 1st luminous intensity distribution peak value side, by the distribution controls of the light from LED12 in the 2nd distribution controls region of the 2nd luminous intensity distribution peak value side and the 3rd distribution controls region between the 1st distribution controls region and the 2nd distribution controls region.

Fig. 6 represents the luminous intensity distribution image of Fig. 5.And Fig. 8 represents by the 1st light distribution characteristic d1 of the 1st distribution controls region luminous intensity distribution, the 2nd light distribution characteristic d2 by the 2nd distribution controls region luminous intensity distribution, the 3rd light distribution characteristic d3 by the 3rd distribution controls region luminous intensity distribution and the light distribution characteristic td by poly-fish lamp entirety overlapping for described light distribution characteristic.As shown in Fig. 6 and Fig. 8,1st luminous intensity distribution peak value P1 is repeated with light (the 3rd luminous intensity distribution) part of the 3rd distribution controls Region control by the light of the 1st distribution controls Region control (the 1st luminous intensity distribution) and is formed, and the 2nd luminous intensity distribution peak value P2 is repeated with light (the 3rd luminous intensity distribution) part of the 3rd distribution controls Region control by the light of the 2nd distribution controls Region control (the 2nd luminous intensity distribution) and formed.Whereby, although be fairly simple formation, the luminous intensity distribution pattern with the 1st luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2 also can be obtained.

Distribution controls component 14 possesses multiple protuberance in the 1st distribution controls region, also possesses multiple protuberance in the 2nd distribution controls region.Namely, by arranging multiple otch (in Fig. 1 (a) and be not particularly illustrated) on the length direction (direction vertical with line segment X-X) of Fig. 1 (a), and look lower the multiple protuberance of formation (with reference to Fig. 1 (b), Fig. 5) in cross section.Each protuberance shape is each other different, controls whereby to the luminous intensity distribution of the light from LED12.

By arranging multiple protuberance in the 1st distribution controls region and the 2nd distribution controls region, with the distribution controls component of embodiment 2 Comparatively speaking, the thickness of distribution controls component 14 self can be reduced, thus the warpage because heat etc. causes can be suppressed.If distribution controls component 14 produces warpage, there is luminous intensity distribution pattern and to change or in order to make distribution controls component self produce the problem such as be full of cracks when suppressing warpage to apply physical force.Therefore, by there is the formation of multiple protuberance and reducing the thickness of distribution controls component 19, the possibility producing described multiple problem can significantly be reduced whereby.

In addition, in this embodiment, be by hull tilt at most ± 20 degree premised on, therefore the 1st luminous intensity distribution peak value P1 is located at-20 degree near, the 2nd luminous intensity distribution peak value P2 is located at+20 degree near.But, the angle of each peak value consider the hull of supposition tilt and determine just can, be not limited to the angle of this embodiment, this is self-evident item.

In this embodiment, when being poly-fish lamp 10 to be arranged on hull, the face (real estate) of substrate 11 is for vertical (direction vertical with sea) is as prerequisite, therefore the luminous intensity distribution pattern that vertical with a real estate and cross section in vertical is looked, consistent with the luminous intensity distribution pattern of the poly-fish lamp 10 irradiated from hull.But, the luminous intensity distribution pattern of poly-fish lamp consider hull situation is set and determine just can, real estate might not be made consistent with vertical.

In this embodiment, the example that the luminous intensity distribution pattern of poly-fish lamp 10 comprises the 1st luminous intensity distribution peak value and the 2nd these 2 luminous intensity distribution peak values of luminous intensity distribution peak value is illustrated, but the present invention is not limited thereto.Namely, as long as make when hull maximum inclination the illumination of any one in the 2nd luminous intensity distribution peak value or the 1st luminous intensity distribution peak value penetrate sea, a distant place just can (with reference to Fig. 3 (b), (c)), such as also can have the 3rd luminous intensity distribution peak value between.But when arranging the 3rd luminous intensity distribution peak value between, the light of the 2nd luminous intensity distribution peak value and the 3rd luminous intensity distribution peak value is not irradiated to sea but irradiates to overhead, the Yan Bujia with regard to light utilization ratio aspect under the state of Fig. 3 (c).Therefore, preferably controlling as such as having the 1st luminous intensity distribution peak value and the 2nd luminous intensity distribution peak value as this embodiment, under the state of hull maximum inclination, the illumination of any one in the 1st luminous intensity distribution peak value or the 2nd luminous intensity distribution peak value can be utilized to penetrate sea, a distant place.

Below, the main composition key element of the poly-fish lamp 10 of this embodiment is described.

(substrate 11)

Substrate 11 is not particularly limited, and is the so-called printed circuit board (PCB) using multi-ply construction and interlayer to implement specific routing model in this embodiment.Printed circuit board (PCB) because of versatility high and easily can form required routing model and preferably.

(LED12)

Light source is not particularly limited, such as, can use LED12 as this embodiment.Also can consider the visual sense degree of catches and use the LED of required wavelength.Such as, the maximum visual sense degree wavelength of inkfish is about 480nm ~ 490nm, therefore can use the LED with the luminescent spectrum of peak wavelength near 480nm ~ 490nm when catching object and being inkfish.

(framework 13)

The framework holding substrate 11 can use various material, various formation.In this embodiment, the principal component of framework 13 is aluminium, carries out efficiently radiates heat to the heat of LED12.In addition, by the bottom of framework 13 is set to fin-like to guarantee large surface area, also thermal diffusivity can be improved further.

(distribution controls component 14)

Distribution controls component 14 is used for controlling the luminous intensity distribution from the light of LED12, such as, formed by resins such as PC (polycarbonate, Merlon).Herein, by distribution controls component 14, and form the 1st different each other luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2.But, when needing the operation more complicated than this embodiment, such as also can arbitrary disposition luminous intensity distribution pattern and the different multiple LED of luminous intensity, realize the luminous intensity distribution pattern comprising the 1st different each other luminous intensity distribution peak value P1 and the 2nd luminous intensity distribution peak value P2.

(embodiment 2)

In this embodiment, only distribution controls component 24 is different, and other form with the poly-fish lamp 10 of embodiment 1 common.Distribution controls component 24 shown in Fig. 7 is so-called lens pillars, in order to obtain the 1st luminous intensity distribution peak value P1, wherein one has curved surface (left side of Fig. 7) by a small margin, in order to obtain the 2nd luminous intensity distribution peak value P2, another one has significantly curved surface (right side of Fig. 7), and both are integrally formed with jump.This kind forms the luminous intensity distribution pattern that also can obtain as shown in Figure 4.

Claims (4)

1. a poly-fish lamp, is arranged on hull, irradiates sea, it is characterized in that:

A plane orthogonal with described sea has the luminous intensity distribution pattern comprising the 1st luminous intensity distribution peak value and the 2nd luminous intensity distribution peak value, and at described hull without under the state of rocking, described 1st luminous intensity distribution peak value is in below horizontal, and described 2nd luminous intensity distribution peak value is in more than level.

2. poly-fish lamp according to claim 1, is characterized in that:

The intensity of described 1st luminous intensity distribution peak value is less than the intensity of described 2nd luminous intensity distribution peak value.

3. poly-fish lamp according to claim 1 and 2, is characterized in that:

The standby LED as light source of described poly-fish light fixture and the distribution controls component controlled from the luminous intensity distribution of the light of described LED,

Described distribution controls component to comprise the distribution controls of the light from described LED in the 1st distribution controls region of described 1st luminous intensity distribution peak value side, by the distribution controls of the light from described LED in the 2nd distribution controls region of described 2nd luminous intensity distribution peak value side and the 3rd distribution controls region between described 1st distribution controls region and described 2nd distribution controls region

Described 1st luminous intensity distribution peak value is repeated by the light part of the light of described 1st distribution controls Region control and described 3rd distribution controls Region control and formed,

Described 2nd luminous intensity distribution peak value is repeated by the light part of the light of described 2nd distribution controls Region control and described 3rd distribution controls Region control and formed.

4. poly-fish lamp according to claim 3, is characterized in that:

Under one cross sectional view, described distribution controls component possesses multiple protuberance in described 1st distribution controls region, possesses multiple protuberance in described 2nd distribution controls region.