Traffic and transportation supply and demand information exchange system
Technical Field
The invention belongs to the field of transportation, and particularly relates to a transportation supply and demand information communication system.
Background
The information exchange system for transportation is a device installed on a road, detects vehicles running in a distributed arrangement mode, is mainly applied to flow monitoring and speed monitoring of the vehicles, and feeds back the flow monitoring and speed monitoring to a transportation system terminal after systematic calculation.
Based on the findings of the inventor, the following defects mainly exist in the prior art, such as: when utilizing the infrared ray among the equipment to vehicle in going to calculate speed, need with infrared irradiation to the accepting equipment of the other end in, and when using equipment under the rainy environment, the rainwater of drippage can be along the equipment irradiation mouth of soaking the infrared ray, makes infrared irradiation mouth surface be stained with and adheres to the water stain, and the infrared ray can form irregular refraction when penetrating through the water stain when equipment is irradiating the infrared ray, leads to the infrared ray to be the outside irradiation of scattered form, makes receiving equipment be difficult to accurate response infrared ray.
Therefore, it is necessary to provide a transportation supply and demand information communication system.
Disclosure of Invention
In order to solve the problems that when the infrared ray in the equipment is used for calculating the speed of a running vehicle, the infrared ray needs to be irradiated to the receiving equipment at the other end, when the equipment is used in a rainy environment, dripping rainwater can soak the infrared ray irradiation port along the equipment, so that the surface of the infrared ray irradiation port is stained with water stains, when the equipment irradiates the infrared ray, the infrared ray can form irregular refraction when penetrating through the water stains, the infrared ray is outwards irradiated in a scattering state, and the receiving equipment is difficult to accurately sense the infrared ray.
The invention relates to a purpose and an effect of a traffic and transportation supply and demand information exchange system, which are achieved by the following specific technical means: the infrared tube is embedded on the right side of the starting button, the starting button is embedded and clamped on the outer side surface of the lower end of the machine body, the fixing hole is embedded and clamped on the outer side end surface of the machine body, and the machine body is embedded, clamped and connected with the inner side end surface of the infrared tube; the infrared tube comprises a protective cover, an irradiation mechanism and a fixed plate, the protective cover is embedded and wrapped on the outer end face of the right side of the irradiation mechanism, the irradiation mechanism is embedded and fixedly installed on the end face of the right side of the fixed plate, and the fixed plate is embedded and clamped with the inner end face of the left side of the protective cover.
The protective cover comprises a leakage hole, a rubber ring, a guide mechanism and an arc-shaped ring, wherein the leakage hole is embedded in the inner side end face of the guide mechanism, the guide mechanism is connected to the end face of the right side of the rubber ring in a fitting manner, the guide mechanism is located on the right side of the arc-shaped ring, the arc-shaped ring is wrapped on the longitudinal outer contour of the rubber ring in a fitting manner, the leakage hole and the adjacent angle of the arc-shaped ring are designed in a gradual sinking manner, and the inner contour of the leakage hole is designed in an arc manner.
Wherein, the arcuation encircles including circular arc piece, guide strip, cotton, solid fixed ring absorb water, the laminating is being connected guide strip is inlayed to circular arc piece left side terminal surface, guide strip is located solid fixed ring's upper end left surface, the cotton laminating parcel that absorbs water is at the lower extreme lateral surface of guide strip, gu fixed ring inlays the left side lower extreme of connecting at the circular arc piece, guide strip can make it form the collection along guide strip flow to the cotton that absorbs water in the guide strip through the laminating at the right-hand end face of fixed plate.
The guide mechanism comprises an embedded and fixed block, a guide block, a cotton interlayer and a second rubber ring, wherein the embedded and fixed block is symmetrically arranged at the upper end and the lower end of the second rubber ring, the guide block is embedded and fixedly arranged at the right side end face of the embedded and fixed block, the inner side end face of the cotton interlayer is embedded, adhered and connected with the second rubber ring, the inner side end face of the guide mechanism is embedded in the second rubber ring, and the right side end face of the guide block is designed in a circular arc shape.
Wherein, shine the mechanism and include mosaic, cover mechanism, rectangular mirror, infrared lamp, collect the mirror, the terminal surface inlays under the mosaic and links firmly the rectangular mirror after that, the mosaic up end is inlayed the block and is being connected and is covering the mechanism, cover the mechanism and be located the infrared lamp directly over, the laminating is inlayed at the lower terminal surface that collects the mirror to the rectangular mirror, the infrared lamp is inlayed and is located the upper end surface of mosaic, it is located the inboard terminal surface down that covers the mechanism to collect the mirror, the rectangular mirror is under the narrow wide rectangle formula design.
The shielding mechanism comprises an irradiation hole, a water flowing hole, a second embedding and fixing block and a leakage plate, the irradiation hole is embedded in the end face of the inner side of the shielding mechanism, the water flowing hole is located on the inner side face of the lower end of the irradiation hole, the second embedding and fixing block is embedded and fixed on the end face of the right side of the leakage plate, the leakage plate is embedded in the lower end face of the inner side of the irradiation hole, and the height of the leakage plate is lower than that of the second embedding and fixing block and is in an inclined design.
Compared with the prior art, the invention has the following beneficial effects:
1. because the inner end surface of the left side of the arc-shaped ring is attached to the outer end surface of the fixing plate, and the guide strip and the absorbent cotton are arranged in the arc-shaped ring, water flow can be guided downwards to the absorbent cotton wrapped outside the arc-shaped ring through the guide strip, water stains are adsorbed by the absorbent cotton to form condensation, then the water stains are discharged downwards to the upper end surface of the leakage hole along the fixing ring and the arc block, and the water flow is discharged outwards by guiding the inner contour of the leakage hole.
2. Because the outer profile of the shielding mechanism is designed in an arc shape, and the descending slope type height difference is arranged between the second embedded and fixed block and the leakage plate, when rainwater flows downwards into the irradiation hole on the outer profile of the shielding mechanism, the rainwater can be collected by the leakage plate through the height difference between the two blocks and is discharged outwards along the water flowing hole, and diffraction caused by irradiation of infrared rays adhered to the inner side end face of the shielding mechanism is avoided.
Drawings
Fig. 1 is a schematic overall structure diagram of a transportation supply and demand information communication system according to the present invention.
Fig. 2 is a schematic structural diagram of an infrared tube of a transportation supply and demand information communication system of the invention.
Fig. 3 is a schematic structural diagram of a protective cover of a transportation supply and demand information communication system of the invention.
Fig. 4 is a schematic structural diagram of an arc-shaped ring of a transportation supply and demand information communication system of the present invention.
Fig. 5 is a schematic structural diagram of a guiding mechanism of a transportation supply and demand information communication system according to the present invention.
Fig. 6 is a schematic structural diagram of an irradiation mechanism of a transportation supply and demand information communication system according to the present invention.
FIG. 7 is a schematic structural diagram of a covering mechanism of the transportation supply and demand information communication system of the present invention.
In the figure: the device comprises an infrared tube-1, a start button-2, a fixed hole-3, a machine body-4, a protective cover-11, an irradiation mechanism-12, a fixed plate-13, a leakage hole-111, a rubber ring-112, a guide mechanism-113, an arc ring-114, an arc block-141, a guide strip-142, absorbent cotton-143, a fixed ring-144, an embedding block-131, a guide block-132, a cotton interlayer-133, a second rubber ring-134, an embedding sheet-121, an embedding block-122, a covering mechanism-123, a rectangular mirror-124, an infrared lamp-125, a collecting mirror-126, an irradiation hole-231, a water flowing hole-232, a second embedding block-233 and a leakage plate-234.
Detailed Description
The invention is further described below with reference to the accompanying drawings:
example 1:
as shown in figures 1 to 5:
the invention provides a traffic and transportation supply and demand information exchange system which structurally comprises an infrared tube 1, a starting button 2, a fixing hole 3 and a machine body 4, wherein the infrared tube 1 is embedded in the right side of the starting button 2, the starting button 2 is embedded and clamped and installed on the outer side surface of the lower end of the machine body 4, the fixing hole 3 is embedded and clamped and installed on the outer side end surface of the machine body 4, and the machine body 4 is embedded, clamped and connected with the inner side end surface of the infrared tube 1; the infrared tube 1 comprises a protective cover 11, an irradiation mechanism 12 and a fixing plate 13, wherein the protective cover 11 is embedded and wrapped on the outer end face of the right side of the irradiation mechanism 12, the irradiation mechanism 12 is embedded and fixedly installed on the end face of the right side of the fixing plate 13, and the fixing plate 13 is embedded, clamped and connected with the inner end face of the left side of the protective cover 11.
The protective cover 11 includes a leakage hole 111, a rubber ring 112, a guiding mechanism 113, and an arc ring 114, the leakage hole 111 is embedded in an inner end face of the guiding mechanism 113, the right end face of the rubber ring 112 is attached to the guiding mechanism 113, the guiding mechanism 113 is located on the right side of the arc ring 114, the arc ring 114 is attached to and wrapped around a longitudinal outer contour of the rubber ring 112, adjacent corners of the leakage hole 111 and the arc ring 114 are designed to gradually sink, and an inner contour of the leakage hole is designed to be an arc shape, so that water flow can be effectively guided to be discharged outwards.
The arc-shaped ring 114 comprises an arc block 141, a guide strip 142, absorbent cotton 143 and a fixing ring 144, the guide strip 142 is connected to the left end face of the arc block 141 in an embedded and fitted manner, the guide strip 142 is located on the left side face of the upper end of the fixing ring 144, the absorbent cotton 143 is wrapped on the outer side face of the lower end of the guide strip 142 in a fitted manner, the fixing ring 144 is connected to the lower end of the left side of the arc block 141 in an embedded and fitted manner, and the guide strip 142 guides flowing water to flow along the guide strip 142 to the absorbent cotton 143 to form collection through fitting on the right end face of the fixing plate 13.
The guide mechanism 113 comprises embedded blocks 131, guide blocks 132, a cotton interlayer 133 and a second rubber ring 134, the embedded blocks 131 are symmetrically installed at the upper end and the lower end of the second rubber ring 134, the guide blocks 132 are embedded and installed at the right end face of the embedded blocks 131, the inner end face of the cotton interlayer 133 is embedded, attached and connected with the second rubber ring 134, the second rubber ring 134 is embedded and arranged at the inner end face of the guide mechanism 113, and the right end face of the guide blocks 132 is in an arc-shaped design, so that water flows along the outer contour of the guide blocks 132 in the flowing process.
The specific use mode and function of the embodiment are as follows:
before the device is used, the whole device is fixed on a monitoring road section of a road through the fixation of the fixing hole 3, after the device is started through the starting button 2, the speed of a car in the driving process is detected through the mutual matching of the infrared tube 1 and the receiving device, when the device is used in rainy days, in order to avoid the formation of infrared scattering caused by the adhesion of rainwater, the leakage hole 111 and the arc-shaped ring 114 are arranged in the protective cover 11, when the rainwater flows on the outer wall of the protective cover 11, because the inner end surface of the left side of the arc-shaped ring 114 is attached to the outer end surface of the fixing plate 13, the guide strip 142 and the absorbent cotton 143 are arranged in the arc-shaped ring 114, the water flow can be guided downwards to the absorbent cotton 143 wrapped at the outer side through the guide strip 142, the water stain is adsorbed by the water absorption of the absorbent cotton 143 to form condensation, and then is downwards discharged to the upper end surface of the leakage hole 111 along the fixing ring 144 and the arc block 141, the water flow is discharged outwards by means of the inner profile guidance of the weep hole 111.
Example 2:
as shown in fig. 6 to 7:
the irradiation mechanism 12 comprises a mosaic sheet 121, a mosaic block 122, a covering mechanism 123, a rectangular mirror 124, an infrared lamp 125 and a collecting mirror 126, wherein the lower end face of the mosaic sheet 121 is fixedly embedded with the rectangular mirror 124, the upper end face of the mosaic block 122 is embedded, clamped and connected with the covering mechanism 123, the covering mechanism 123 is positioned right above the infrared lamp 125, the rectangular mirror 124 is embedded and attached to the lower end face of the collecting mirror 126, the infrared lamp 125 is embedded and arranged on the upper end face of the mosaic block 122, the collecting mirror 126 is positioned on the inner lower end face of the covering mechanism 123, the rectangular mirror 124 is in a rectangular design with a narrow top and a wide bottom, and infrared rays emitted outwards along the infrared lamp 125 can be formed through the structural design of the rectangular mirror 124 to be collected and irradiated outwards along the covering mechanism 123.
The covering mechanism 123 comprises an irradiation hole 231, a water flowing hole 232, a second embedding and fixing block 233 and a leakage plate 234, the irradiation hole 231 is embedded in the inner side surface of the covering mechanism 123, the water flowing hole 232 is located on the inner side surface of the lower end of the irradiation hole 231, the second embedding and fixing block 233 is embedded and fixed on the right side end surface of the leakage plate 234, the leakage plate 234 is embedded in the inner lower end surface of the irradiation hole 231, the leakage plate 234 is lower than the second embedding and fixing block 233 in height and is in an inclined design, and water flowing to the leakage plate can flow along the water flowing hole 232 to be discharged outwards along the height difference formed by the second embedding and fixing block 233 and the leakage plate 234.
The specific use mode and function of the embodiment are as follows:
the infrared lamp 125 can irradiate infrared rays to the outside during the use process of the invention, and the rectangular mirror 124 attached to the lower end surface of the collecting mirror 126 is designed to be narrow at the top and wide at the bottom during the irradiation process, so that the infrared rays can be gathered and collected towards the middle along with the rectangular mirror 124 during the irradiation process of the infrared rays to form a focus point of the infrared rays, when the collected infrared rays are irradiated to the masking mechanism 123 along the collecting mirror 126, they are irradiated out along the irradiating hole 231, since the outer contour of the masking mechanism 123 is designed to be circular arc and a descending slope type height difference is provided between the second embedded block 233 and the leakage plate 234, when rainwater flows down into the irradiation hole 231 on the outer contour of the masking mechanism 123, the infrared radiation can be prevented from being adhered to the inner end of the masking mechanism 123 and being diffracted by the infrared radiation because the infrared radiation is collected by the leakage plate 234 due to the height difference between the two and is discharged outside along the water flow hole 232.
The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.