CN216663692U - Synchronous chip seal paver - Google Patents

Abstract

The utility model discloses a synchronous macadam seal layer paver integrating receiving, transferring and batching, minimally invasive pretreatment, asphalt spraying, macadam spreading and dust removal. After receiving and buffering all raw materials, metering and spraying asphalt and spreading broken stones for paving, and performing pretreatment and dust removal on minimally invasive milling and brushing and minimally invasive punching and milling of the road surface in real time. The operation and control are simple, the material receiving is easy and convenient, the yield is large, the efficiency is high, and the performance is stable, reliable and durable; the spraying and spreading width is wide, the change is flexible, and the precision is high; the problems of longitudinal and transverse seams and stub bars are effectively solved, and the phenomena of different pavement qualities are avoided; uniform spraying and spreading, strong interlayer adhesive force, excellent quality and performance and prolonged service life of the pavement. Is suitable for construction in various operation surfaces and environments. The peak reaching by carbon and the neutralization by carbon are met.

Description

Synchronous chip seal paver

Technical Field

The utility model belongs to the field of engineering machinery required by road and airport construction, maintenance and repair and other pavement operations. In particular to a synchronous chip sealer.

Background

The synchronous chip seal technology becomes an important component in road construction and pavement maintenance and repair engineering. The synchronous chip seal is carried out by spraying asphalt (modified asphalt, etc.) and spreading mineral aggregate simultaneously, so that the asphalt binder and mineral aggregate have sufficient contact to reach maximum adhesion degree to form a thin layer of pavement. The method can be used for performing preventive maintenance, early maintenance, rut filling and repairing, pavement appearance improvement and the like on the surface function of the road. The adhesive has the functions of adhesion, water resistance and the like in the lower sealing layer in the construction of road surfaces, airport runways and the like. Effectively improve road service performance and prolong road service life. The synchronous gravel seal layer paving equipment and the construction technical method have important influence on construction quality and performance.

At present, the domestic synchronous chip sealer construction generally adopts an operation mode that a synchronous chip sealer vehicle carries out an intermittent process. The method comprises the steps of firstly filling raw materials such as mineral aggregate, asphalt and the like in a stock yard, then driving the stock yard to a construction site to carry out construction operation, and when a certain raw material is used up, obtaining the stock yard again to be filled, and repeating the construction. Because synchronous chip seal car is every full a car raw and other materials quantity restriction, the area that can pave is limited to different width and mineral aggregate density and pitch spraying volume restraint in addition, and equipment must return to the stock ground and install the raw and other materials in the construction of long distance big engineering and arrive at the building site again and carry out the construction operation next time. Therefore, most time of equipment is wasted on transporting raw materials, high equipment utilization rate is low, and construction efficiency is not ideal. Usually, a plurality of devices are adopted to sequentially operate in turn in large-scale engineering, so that paving joints are easy to frequently occur in the long-distance construction process to influence the quality of the whole pavement. The low-speed and constant-speed running of the truck chassis under the working conditions of heavy load and load change in the construction process is difficult to control; the low-speed and uniform-speed running range of the truck chassis is very limited, and the control and the adjustment are more difficult to realize under the working condition of heavy load and load change. The reduction ratio of the truck chassis gearbox is also troubled by the fact that the low-speed construction speed and the high-speed transportation running speed cannot be achieved at the same time. Different operation personnel of different model equipment often can take place different shop front quality phenomena at same construction road section construction operation, especially different appearance quality problem. In addition, each operation necessarily generates a process stub bar, and the produced stub bars influence the overall construction quality in different degrees.

At present, the prior continuous type synchronous macadam seal equipment and technology adopts an asphalt spreader to spray asphalt firstly, and then the continuous type macadam spreader spreads mineral aggregate. However, the foreign continuous equipment introduced in the real production has not been accepted and recognized by the domestic market and industry for a long time! The synchronous broken stone seal layer vehicle construction is widely used in China for a long time. Although the related technologies of continuous synchronous chip sealer and construction method are disclosed and introduced in quite a lot of literature documents, the operability, popularization, reliability, construction quality, cost and the like of the continuous synchronous chip sealer are far from the comprehensive application performance of the synchronous chip sealer, and the real object is rarely seen in the actual production. The reason for this phenomenon is mainly three-fold: firstly, the existing continuous and synchronous chip sealer has strict requirements on the level of construction operation and managers; secondly, the continuous feeding process is complicated, the operation is not easy, and the construction quality is difficult to control; and then the continuous, smooth and stable matching operation among matched equipment is achieved, and the operation is complex and very difficult. The above problems have been long-standing.

Since the existing equipment design shows: the effective power of the equipment is limited, and the spraying and spreading width is limited, so that the one-time performance of the existing continuous and discontinuous synchronous stone crushing process meets the requirement of spreading the stone in the width of one lane. Therefore, the pavement of more than two lanes adopts a sequential splicing mode, so that the distribution ratio generated at the longitudinal and transverse joints is not uniform, the flatness of the joints is easy to generate unevenness and leakage pavement, the lap joint bonding degree and strength of the joints are unstable, and the quality problems of the integral pavement flatness, appearance color difference and the like are very difficult to control.

A great deal of research at home and abroad shows that the inadequate treatment between pavement layers is one of the important reasons for causing the quality problem of the pavement of the synchronous chip seal. Because the original road surface layer and the synchronous chip seal surface layer are made of two materials and processes with different structures, if the interlayer binding force is insufficient, the load brought by road traveling, particularly heavy load and overload, is added alternately in four seasons through the natural environment, and the interlayer extrusion and shearing deformation are accumulated continuously, so that the synchronous chip seal surface pavement has pavement diseases such as premature falling, cracks, pitted surfaces, oil bleeding and the like.

In addition, the existing equipment design scheme shows that: the effective power of the equipment is limited, and the functionality is single, so that when the pretreatment process is carried out on the pavement by the synchronous chip sealer at present, the pretreatment process needs to be carried out in advance by using separate equipment. Therefore, the mineral aggregate scattered in the construction process cannot be cleaned in time, the bonding quality problem is caused, and the whole paving quality effect is directly influenced. In particular to a method for preprocessing the road surface before the synchronous gravel paving construction at present, which generally adopts non-special cleaning equipment and a shoulder portable blower to preprocess the road surface before the construction. The method obviously has very limited cleaning effect on the road surfaces of the deposited ash layer, the asphalt oxidation layer, the unstable material and the like of the original road surface, and can not meet the design requirement of the construction process. And the method is very labor-consuming, time-consuming, low in construction efficiency, large in occupied equipment and manpower, high in construction cost, uneconomical and not suitable for carbon peak reaching and carbon neutralization.

The above problems have not been solved effectively.

Disclosure of Invention

The utility model aims to solve the technical defects, and provides an intelligent synchronous chip seal paver and a construction technical method, which can simultaneously perform the following steps: the process procedures of receiving materials, measuring and transferring raw materials, carrying out minimally invasive pretreatment (high-pressure water minimally invasive punching and milling and minimally invasive milling and brushing), spraying asphalt, spreading broken stones, removing dust and the like are integrated into a whole to complete paving or track filling operation at one time. The utility model has two functions of continuous construction and intermittent construction; the asphalt and gravel are sprayed with high accuracy and measurement, and the pavement is uniformly paved; the spreading width can be spread by spraying, and the single-lane spreading can be realized, and the multi-lane one-step spreading can also be realized, and the construction operation width is simple, flexible and various; the 'dry' and 'wet' minimally invasive pretreatment devices are specially and innovatively designed to implement minimally invasive punching and milling and minimally invasive milling and brushing so as to remarkably enhance the interlayer adhesive force of the pavement; the intelligent material conveying device has the advantages of intellectualization, simple and easy operation, and particularly simple, convenient and quick material conveying among devices. Particularly, the design scheme is innovative and novel, and can be used for continuously and simply transferring and supplying raw materials with a general dump truck and an asphalt transport vehicle in a synchronous, simple, convenient, easy and quick way in the construction process without other special supporting equipment, so that the long-distance multi-lane large-width continuous construction operation without stopping smoothly and stably is realized. The utility model is easy, simple and intelligent to operate; the problems of longitudinal seams, transverse seams and stub bars are effectively solved; the phenomena of the appearance color difference and different paving quality of the pavement are eliminated; the minimally invasive pretreatment design obviously enhances the interlayer adhesive force and reduces the premature occurrence of pavement diseases. The utility model has accurate and sensitive asphalt spraying and gravel spreading precision, uniform and efficient spraying and spreading and large yield; the paving width can be adjusted in a wide and flexible range, the maximum paving width can reach over 12.5 meters at one time, and the paving width has larger width expansion potential; the travelling speed is stable and adjustable during construction operation, and the paving speed is constant and powerful; the stepless flexible control and regulation can be realized from low speed to high speed, and the operation is smooth and stable; the construction quality and performance are excellent, the low carbon and environmental protection are realized, and the service life of the pavement is prolonged. The utility model has scientific and reasonable structural layout, reliable and durable performance, lower use and maintenance cost and high cost performance. Is suitable for construction in various working surfaces and environments.

In order to achieve the purpose, the utility model provides the following technical scheme: a synchronous macadam seal coat paver is characterized by comprising a rack (namely a chassis), an internal combustion engine, a transfer case, a hydraulic system, an air circuit system, a circuit system, an operation platform and control system, a push roller, a push shovel device, a walking device, a receiving hopper, a mineral aggregate transferring system, an asphalt heating and heat insulating device, an asphalt spraying device, a macadam spreading device and a dust removing device. And the left side and the right side of the bottom of the rack are symmetrically provided with walking devices in parallel. The internal combustion engine and the transfer case are fixed in the rear part of the frame above the walking device, the power input port of the transfer case is in transmission connection with the power output port of the crankshaft of the internal combustion engine, the power is distributed by the transfer case, each power output port of the transfer case is in transmission connection with a hydraulic pump matched with each function so as to drive components such as a hydraulic motor, a hydraulic oil cylinder and the like of each function, and the power take-off port of the internal combustion engine is in transmission connection with a corresponding hydraulic pump so as to drive components such as a corresponding hydraulic motor or a hydraulic oil cylinder and the like. The asphalt heating and heat insulating device is arranged on the upper sides of the internal combustion engine and the transfer case and is fixed on the frame. The front end of the frame is provided with a pushing roller for pushing the tires of the mineral aggregate conveying vehicle to move ahead synchronously. The gravel spreading device is arranged at the tail of the machine frame. A receiving hopper is hinged above the front part of the frame, and the opening and closing functions can be implemented through a hydraulic oil cylinder, so that the smooth blanking of mineral aggregate is guaranteed. A mineral aggregate transferring system is arranged at a space position between the bottom of the receiving hopper and the lower side of the bottom of the internal combustion engine and between the asphalt heating and heat insulating device and the gravel spreading device, and mainly comprises a I-level parallel conveying functional mechanism and a II-level lifting functional mechanism; the feed inlet of the mineral aggregate transferring system is communicated with the discharge outlet of the receiving hopper; and the discharge hole of the mineral aggregate transferring system is arranged above the feed inlet of the gravel spreading device and communicated with the feed inlet. The asphalt spraying device is arranged in a space position between the lower part of the rear part of the frame and the rear part of the walking device and the front part of the outlet of the gravel spreading device, and asphalt is conveyed by an asphalt spraying pump. The control platform and the control system (control cabinet) are arranged behind the frame and at the front side or the rear side of the gravel spreading device.

The mineral aggregate transferring system comprises a mineral aggregate conveying device I, a mineral aggregate lifting device and a mineral aggregate conveying device III, and is used for respectively realizing I-level parallel conveying, II-level lifting conveying and III-level parallel conveying, so that the mineral aggregate in the receiving hopper is transferred to the broken stone spreading device together, and the transferring feeding amount is measured and controlled. The mineral aggregate conveying device I is arranged on the lower side of the bottom of the receiving hopper, a feed inlet of the mineral aggregate conveying device I, namely a feed inlet of the mineral aggregate transferring system, is communicated with a discharge outlet of the receiving hopper, and a discharge outlet of the mineral aggregate conveying device I is communicated with a feed inlet of the mineral aggregate lifting device; the mineral aggregate lifting device is arranged in a space position between the rear side of the receiving hopper and the front side of the internal combustion engine and is fixed on the frame; the mineral aggregate conveying device IV is arranged below the discharge hole of the mineral aggregate lifting device and above the asphalt heating and heat insulating device and is fixed on the frame, the discharge hole of the mineral aggregate lifting device is communicated with the feed inlet of the mineral aggregate conveying device IV, and the feed inlet of the gravel dispensing device is arranged under the discharge hole of the mineral aggregate conveying device IV (namely the discharge hole of the mineral aggregate conveying system) and is communicated with the feed inlet.

In the above scheme, the first choice of the mineral aggregate conveying device i is a chain scraper conveyor, or a chain slat conveyor, or a spiral conveyor, or a chain belt (combination of a chain and a belt) conveyor, or a belt conveyor. The driving sprocket shaft, or the screw shaft, or the belt roller shaft of the mineral aggregate conveying device I is in transmission connection with the speed reducer of the mineral aggregate conveying device I, the speed reducer of the mineral aggregate conveying device I is in transmission connection with the hydraulic motor of the mineral aggregate conveying device I, and the hydraulic motor of the mineral aggregate conveying device I is driven by the hydraulic pump which is connected with the transfer case in transmission connection and matched with the transfer case.

In the above scheme, the mineral aggregate lifting device is preferably a hopper lifter, and may also be a large elevation angle belt lifter, or a large elevation angle chain belt (combination of chain and belt) lifter, or a scraper lifter. The driving chain wheel shaft or the belt roller shaft of the mineral material lifting device is in transmission connection with a speed reducer of the mineral material lifting device, the speed reducer of the mineral material lifting device is in transmission connection with a hydraulic motor of the mineral material lifting device, and the hydraulic motor of the mineral material lifting device is driven by a hydraulic pump matched with the hydraulic motor and in transmission connection with a transfer case.

In the above scheme, the first choice of the mineral aggregate conveying device iv is a belt conveyor, and may also be a chain scraper conveyor, a chain slat conveyor, a continuous (combination of a chain and a belt) conveyor, or a screw conveyor. The driving belt roller shaft, or the chain wheel shaft, or the spiral shaft of the mineral aggregate conveying device IV is in transmission connection with a mineral aggregate conveying device IV speed reducer, the mineral aggregate conveying device IV speed reducer is in transmission connection with a mineral aggregate conveying device IV hydraulic motor, and the mineral aggregate conveying device IV hydraulic motor is driven by a hydraulic pump matched with the mineral aggregate conveying device IV hydraulic motor and in transmission connection with the transfer case.

The mineral aggregate transferring system comprises a mineral aggregate conveying and lifting device V and a mineral aggregate conveying device IV, so that the mineral aggregate in the receiving hopper is transferred to the gravel scattering device together, and the transferring feeding amount is measured and controlled. The mineral aggregate conveying and lifting device V is arranged at the lower side of the bottom of the receiving hopper and at the space position between the rear side of the receiving hopper and the front side of the internal combustion engine and is fixed on the frame, and the mineral aggregate conveying and lifting device V is arranged below a material opening and on the upper side of the asphalt heating and heat insulating device and is fixed on the frame. A feeding hole of the mineral aggregate conveying and lifting device V (namely a feeding hole of the mineral aggregate transferring system) is communicated with a discharging hole of the receiving hopper; the discharge hole of the mineral aggregate conveying and lifting device V is communicated with the feed hole of the mineral aggregate conveying device IV; a feeding hole of a gravel spreading device is arranged under a discharge hole (namely a discharge hole of the mineral aggregate transferring system) of the mineral aggregate conveying device IV and is communicated with the feeding hole.

In the scheme, the mineral aggregate conveying and lifting device V simultaneously comprises I-level parallel conveying and II-level lifting functions and is fixed on the rack, and the mineral aggregate conveying device IV realizes the III-level parallel conveying function. The mineral aggregate conveying and lifting device V is preferably a hopper type lifting conveyor, and can also be a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor. The driving chain wheel shaft or the belt roller shaft of the mineral aggregate conveying and lifting device V is in transmission connection with a mineral aggregate conveying and lifting device V speed reducer, the mineral aggregate conveying and lifting device V speed reducer is in transmission connection with a mineral aggregate conveying and lifting device V hydraulic motor, and the mineral aggregate conveying and lifting device V hydraulic motor is driven by a hydraulic pump matched with the mineral aggregate conveying and lifting device V and in transmission connection with a transfer case.

The mineral aggregate transferring system comprises a mineral aggregate conveying device I and a mineral aggregate lifting and conveying device VI, so that the mineral aggregate in the receiving hopper is transferred to the broken stone spreading device together, and the transferring and conveying feeding amount is measured and controlled. The first mineral aggregate conveying device is arranged on the lower side of the bottom of the receiving hopper, a feed port of the first mineral aggregate conveying device (namely a feed port of a mineral aggregate transferring system) is communicated with a discharge port of the receiving hopper, and a discharge port of the first mineral aggregate conveying device is communicated with a feed port of a mineral aggregate lifting device VI. The mineral aggregate lifting and conveying device VI is arranged at the space position between the rear side of the receiving hopper and the front side of the internal combustion engine and the upper side of the asphalt heating and heat preserving device and is fixed on the rack. A feeding hole of a gravel spreading device is arranged under and communicated with a discharging hole of the mineral aggregate lifting and conveying device VI (namely the discharging hole of the mineral aggregate transferring and conveying system).

In the scheme, the I-level parallel conveying function of the mineral aggregate conveying device is realized, and the VI-level lifting and conveying device simultaneously comprises the II-level lifting and III-level parallel conveying functions and is fixed on the rack. The mineral aggregate lifting and conveying device VI is preferably a hopper type lifting conveyor, and can also be a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor. The driving sprocket shaft or the belt roller shaft of the mineral aggregate lifting and conveying device VI is in transmission connection with a speed reducer of the mineral aggregate lifting and conveying device VI, the speed reducer of the mineral aggregate lifting and conveying device VI is in transmission connection with a hydraulic motor of the mineral aggregate lifting and conveying device VI, and the hydraulic motor of the mineral aggregate lifting and conveying device VI is driven by a hydraulic pump matched with the hydraulic motor and in transmission connection with a transfer case.

The mineral aggregate transferring system comprises a mineral aggregate transferring lifting conveying device VII for transferring the mineral aggregate in the receiving hopper to the gravel scattering device, and the transferring feeding amount is measured and controlled. The mineral aggregate conveying and lifting conveying device VII is arranged at the lower side of the receiving hopper, at the space position between the rear side of the receiving hopper and the front side of the internal combustion engine, and at the upper side of the asphalt heating and heat insulating device and is fixed on the frame. The feed inlet of the mineral aggregate conveying and lifting conveying device VII (namely the feed inlet of the mineral aggregate transferring system) is communicated with the discharge outlet of the receiving hopper, and the feed inlet of the gravel spreading device is arranged under the discharge outlet of the mineral aggregate conveying and lifting conveying device VII (namely the discharge outlet of the mineral aggregate transferring system) and is communicated with the discharge outlet of the receiving hopper.

In the above scheme, the mineral aggregate conveying and lifting conveying device VII simultaneously comprises a I-level parallel conveying function, a II-level lifting function and a III-level parallel conveying function, and is in a step shape. The mineral aggregate conveying, lifting and conveying device VII is preferably a hopper type lifting conveyor, and can also be a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor. The driving sprocket shaft or the belt roller shaft of the mineral aggregate conveying and lifting conveying device VII is in transmission connection with a mineral aggregate conveying and lifting conveying device VII speed reducer, the mineral aggregate conveying and lifting conveying device VII speed reducer is in transmission connection with a mineral aggregate conveying and lifting conveying device VII hydraulic motor, and the mineral aggregate conveying and lifting conveying device VII hydraulic motor is driven by a hydraulic pump which is connected with a transfer case in a transmission connection and matched with the transfer case.

The mechanism component with the III-grade parallel conveying function in the mineral aggregate conveying system can also be arranged at a space position between the lower side of the bottom of the asphalt heating and heat preserving device and the upper side of the top of the internal combustion engine and fixed on the rack; preferably designed on the upper side of the top of the asphalt heating and heat-preserving device.

The mineral aggregate transferring system is provided with a mineral aggregate metering device, and the mineral aggregate transferring system is used for accurately regulating, controlling and metering the mineral aggregate conveying amount. Metering sensors are respectively arranged in the I-level parallel conveying machine, the II-level lifting conveying machine and the III-level parallel conveying machine, and the mineral aggregate conveying device is matched with and coordinates the conveying capacity and speed of a mineral aggregate conveying system through the displacement change or the rotating speed regulation of a variable hydraulic motor or a variable hydraulic pump. The rotation speed is regulated steplessly, and the control of changing the feeding amount of the mineral aggregate conveying system and the metering precision is completed.

The mineral aggregate distributor is arranged on the discharge hole of the mineral aggregate transferring system, or on the feed inlet of the gravel spreading device, or is independently arranged between the discharge hole of the mineral aggregate transferring system and the feed inlet of the gravel spreading device, and the discharge hole of the mineral aggregate transferring system, the mineral aggregate distributor and the feed inlet of the gravel spreading device are communicated. Because the mineral aggregate spreading devices with different structural forms are selected and matched, the requirement on material distribution is different; when a fixed mechanical folding type mineral aggregate spreading device is usually selected for small-width (single-width pavement) spreading, a discharge port of a mineral aggregate conveying device directly feeds into the mineral aggregate spreading device; when the telescopic mineral aggregate spreading device is selected, mineral aggregates are respectively conveyed into a left mineral aggregate distributing and distributing groove and a right mineral aggregate distributing and distributing groove; particularly, when the road surface is spread in large width and over width (a plurality of road surfaces), the mineral aggregate must be respectively conveyed to the left and the right spiral distributing grooves of the corresponding mineral aggregate spreading device. Therefore, the mineral aggregate distributor is designed, mineral aggregates can be effectively distributed when the mineral aggregate distributor feeds materials into the gravel spreading device, and continuous and stable spreading construction operation is ensured.

The asphalt heating and heat-insulating device comprises an asphalt tank, a liquid level sensor, a burner, a combustion chamber, a chimney, an asphalt pipeline, a valve, heat-conducting oil, a heat-conducting oil pipe, a temperature sensor, a temperature controller, a thermometer, a pressure gauge, a pressure sensor, a pressure controller and the like. The asphalt heating and heat-preserving device is used for storing enough asphalt and preserving and heating the asphalt; the asphalt heating and heat insulating device is arranged above the internal combustion engine and the transfer case and is fixed on the frame by bolts.

The asphalt transferring system comprises a feeding asphalt pump I, an asphalt spraying pump, an asphalt conveying pipeline, an asphalt flowmeter, an asphalt pipeline valve, an asphalt multi-way flow divider valve, a thermometer, a pressure gauge, a temperature sensor, a temperature controller, a pressure sensor and a pressure controller. Most parts of the asphalt transferring system are arranged on the two sides of the mineral aggregate lifting device and the rear side of the asphalt heating and heat-preserving device. Feed asphalt pump I and pitch spray pump set up in mineral aggregate hoisting device lower part both sides and fix in the frame, are fixed with feed asphalt pump I and pitch spray pump import respectively in frame center lower part both sides. An inlet and an outlet of the feeding asphalt pump I are respectively connected with an asphalt outlet of the asphalt conveying vehicle and an inlet pipeline of the asphalt heating and heat preserving device, and the feeding asphalt pump I is used for conveying asphalt on the asphalt conveying vehicle into the asphalt heating and heat preserving device; the inlet and the outlet of the asphalt spraying pump are respectively connected with the asphalt heating and heat-insulating device, the valve, the asphalt flowmeter, the asphalt pressure gauge, the inlet of the asphalt spraying device and other pipelines, and the asphalt is conveyed to the asphalt spraying device.

In the above scheme, the asphalt transferring system is provided with an asphalt metering device, which comprises an asphalt flowmeter, a pressure sensor, a rotating speed sensor and the like. The feeding asphalt pump I and the asphalt spraying pump are variable asphalt pumps or variable hydraulic pumps and variable hydraulic motors; the delivery flow and the pressure of the asphalt delivery system are cooperatively and coordinately controlled through the displacement change or the rotating speed regulation of the variable hydraulic motor or the variable hydraulic pump and the opening and closing degree of the valve of the asphalt pipeline. The control of the asphalt spraying amount and the metering precision of the asphalt conveying system is finished. The feeding asphalt pump I and the asphalt spraying pump can also be driven by an electric motor or a variable frequency electric motor, and preferably a hydraulic motor.

The asphalt transferring system further comprises a feeding asphalt pump II, and the feeding asphalt pump II is arranged on the lower portion of the center of the front side or the rear side of the gravel spreading device. And the inlet and the outlet of the feeding asphalt pump II are respectively connected with an asphalt outlet of the asphalt conveying vehicle and an inlet pipeline of the asphalt heating and heat insulating device, and the feeding asphalt pump II is used for conveying asphalt on the asphalt conveying vehicle into the asphalt heating and heat insulating device.

The synchronous chip seal paver also comprises a movable feeding asphalt pump III and a movable water supply pump. When water and asphalt are transferred to the water tank and the asphalt heating and heat insulating device, a movable submersible pump (an asphalt pump and a water pump) can be additionally and independently adopted to be placed in a transport vehicle tank, and an outlet pipeline of the submersible pump is connected with the asphalt heating and heat insulating device and an inlet of the water tank to transfer asphalt and water. The mobile pump is powered by the generator set and is manually or intelligently controlled by the control platform.

The synchronous chip seal paver also comprises a pipeline bracket, and when asphalt in an asphalt truck is conveyed to a green heating and heat-insulating device in the synchronous chip seal paver, an asphalt conveying pipeline is hung on the pipeline bracket. The pipeline is supported in such a way, and the dragging effect on the pipeline caused by asynchronous stopping and starting of the equipment room is eliminated; when the speed of the equipment is different in the walking process, the dragging effect on the pipeline is buffered. Pipeline brackets are arranged on the two sides and the rear side of the synchronous chip sealer paver to ensure the normal work of a conveying pipeline.

The walking device is preferably a crawler-type walking mechanism; or a wheel type walking mechanism, or a crawler and wheel type combined walking mechanism, namely a front wheel rear crawler belt. The crawler-type traveling mechanism driving chain wheel or the wheel-type traveling mechanism wheel drum is in transmission connection with the traveling reducer; the walking speed reducer is connected with the walking hydraulic motor in a transmission way, and the walking hydraulic motor is driven by the walking hydraulic pump matched with the walking hydraulic motor and connected with the transfer case in a transmission way.

In the above scheme, the hydraulic system of the walking device is a closed system. The walking variable hydraulic motor, the variable hydraulic pump and the rotating speed sensor are selected to realize speed regulation. A hydraulic brake device is adopted.

The pushing roller is arranged at the front end of the frame of the synchronous chip seal paver, and when the self-unloading truck unloads materials to the receiving hopper, the pushing roller pushes the rear tires of the self-unloading truck to synchronously advance.

The receiving hopper is formed by two hopper components which are symmetrical left and right, and is designed with opening and closing functions. The receiving hopper is hinged above the front part of the frame, and the receiving hopper is opened and closed through a hydraulic oil cylinder to ensure that mineral aggregates smoothly leak.

The hydraulic system is mainly formed by connecting a hydraulic pump which is connected with a power output port of the transfer case and has matched functions, executing components such as a hydraulic motor, a hydraulic oil cylinder and the like with the functions, an integrated valve block, a functional valve block, a sensor, a hydraulic pipeline and the like.

The gas circuit system can be formed by connecting an air compressor device, an air cylinder and other execution components, an integrated valve block, a functional valve block, a sensor, an air pipe and the like. The control system on the control platform is used for controlling the air cylinder in the punching and milling device so as to realize the opening and closing of the water spray head; controlling an air cylinder in the asphalt spraying device to further open and close an asphalt spray head; and controlling the opening and closing of a valve in the asphalt transferring system, the opening and closing of a valve in the waterway transferring system and the like.

The control platform and the control system (including a control module cabinet) and the electric control cabinet of the generator set are mainly arranged behind the frame, and part of the control modules and the circuit system are arranged at proper positions in different spaces of the body of the synchronous chip seal paver. All functions of the synchronous chip seal paver are intelligently controlled and managed, and electric power energy is provided.

The fiber agent adding system comprises a fiber conveying device and a fiber adding executing device. Realize the addition of fiber in the asphalt spraying and gravel spreading operation engineering.

The gravel spreading device is arranged at the tail of the machine frame. The even accurate dispensing of mineral aggregate can be realized to the rubble dispensing device of the different structural style of selection for use.

The synchronous chip seal paver also comprises a dry-type pretreatment system, namely a minimally invasive milling and brushing device. The minimally invasive milling and brushing device is arranged between the lower part of the rear part of the rack, the rear part of the walking device and the front part of the asphalt spraying device. Used for cleaning the road surface or carrying out minimally invasive finish milling and planing on the road surface. The pavement cleanliness of the to-be-constructed pavement is improved, the adhesion between the paving surface layers of the synchronous gravel sealing layer is enhanced, the paving quality is improved, and the occurrence of pavement diseases is reduced.

The synchronous chip seal paver also comprises a wet-type pretreatment system, namely a minimally invasive punching and milling device. The minimally invasive punching and milling device is arranged between the lower part of the rear part of the rack and the rear part of the walking device and the front part of the asphalt spraying device. And carrying out minimally invasive punching and milling on the surface layer of the road by adopting high-pressure water flow. The pavement cleanliness of the to-be-constructed pavement is improved, the temperature of the pavement is improved, and the adhesion between the paving surface layers of the synchronous gravel seal layer is enhanced, so that the paving quality is improved, and the occurrence of pavement diseases is reduced.

The synchronous broken stone seal paver further comprises a shoveling and pushing device, wherein the shoveling and pushing device is arranged below the front portion of the frame and on the front side of the walking device. The aim of pushing the scattered mineral aggregate and other useless materials to the two sides of the pavement to be constructed is achieved.

The synchronous broken stone seal paver also comprises a dust removal device used for collecting dust generated in the broken stone spreading process. The dust removing device comprises a dust hood, an exhaust fan, a dust filtering device and a dust hood lifting device. The dust excluding hood encloses the wrapping up of rubble dispensing device discharge gate and can fluctuate, and rubble dispensing operation in-process dust excluding hood and road surface keep very little distance with the road surface with do not influence the shop front as the standard, otherwise the dust excluding hood promotes to keep away from the road surface as far as possible. The dust excluding hood is connected with the inlet pipeline of the exhaust fan, and the dust filtering device is connected with the outlet pipeline of the exhaust fan.

Compared with the prior art, the utility model has the following advantages

1. The synchronous chip seal paver of the utility model can simultaneously carry out the following steps: the construction operation can be completed at one time by integrating the process procedures of receiving materials, heating and insulating asphalt, performing minimally invasive pretreatment, spraying asphalt, spreading fibers, spreading broken stones and the like. The equipment and the construction method are suitable for construction operation in various operation surfaces and environments.

2. The material transmission is natural: the utility model has scientific and optimized design for the mineral aggregate transferring system and the asphalt transferring system, and reasonable and scientific layout, thereby having the function of 'continuous' or 'intermittent' construction operation without other special supporting equipment. Namely, the construction process can be synchronously, simply, conveniently, easily, quickly and reliably and continuously transferred and supplied to all raw materials only with a general dump truck and an asphalt transport vehicle. Therefore, continuous constant-speed construction operation without stopping, smoothness, stability and long distance is realized, or the construction site stops on site and carries out intermittent construction operation after the feeding is finished.

3. The width of paving is wide: the asphalt gravel spraying device has the advantages of large spreading width, high asphalt gravel spraying precision, uniformity, flexibility, sensitivity, large yield and high efficiency. Therefore, the device can continuously spray and spread a plurality of pavements with abundant material supply, the maximum one-time spreading width reaches more than 12.5 meters, and the adjustable range of the spraying and spreading width is wide. And has greater width expansion potential. Due to the fact that the paving machine has the function of paving a plurality of road surfaces with super-width, the quality problems of the stub bars, transverse joints and longitudinal joints are effectively solved, and the quality problems of appearance color difference of the road surfaces, unevenness, material leakage and the like at the joints after construction are eliminated.

4. Dry minimally invasive milling: the utility model contains the function of 'dry' minimally invasive milling, brushing, cleaning and finish milling and planing, and efficiently brushes the pavement or carries out minimally invasive milling and brushing pretreatment on the pavement. The interlayer adhesion of the pavement is effectively enhanced; greatly improves the paving quality, reduces the premature occurrence of pavement diseases, thereby prolonging the service life of pavement by times.

5. Wet-type minimally invasive high-pressure punching and milling: the utility model has a 'wet' minimally invasive punching and milling function, namely, the surface layer of the road is subjected to minimally invasive punching and milling pretreatment by adopting high-pressure water flow or the road surface is sprayed with water for wetting and cooling. Effectively enhancing the interlayer adhesive force of the pavement, greatly improving the paving quality, reducing the premature occurrence of pavement diseases, and further prolonging the service life of the pavement by times.

6. Collecting the flying dust: the dust removing device has a dust removing function, and collects dust generated in the process of spreading broken stones and the working process of the minimally invasive milling and brushing device.

7. And (3) automatically removing materials: the utility model contains the push shovel device, is similar to a push shovel of a bulldozer, pushes and removes the scattered and dropped mineral aggregate and other pavement remaining materials to two sides, does not need manual removal treatment, enables the linear walking of the crawler walking device not to be influenced, is beneficial to the linear and uniform walking of the synchronous broken stone seal paver, and has convenient and rapid cleaning and safer use.

8. Paving at a constant speed: the utility model adopts the design of full hydraulic closed system walking drive, the constant speed advancing speed is stable during construction operation, and the stepless regulation from low speed to high speed is flexible, smooth, powerful and stable, thereby ensuring that the construction is not influenced under the working conditions of heavy load and load change, and the pavement quality performance is excellent and outstanding.

9. The operation is simple: the road surface spraying and spreading device can complete continuous feeding, continuous spraying and spreading of the road surface by only one person, is convenient to operate, is intelligent and saves manpower.

10. High effective power and strong capacity expansion: the utility model adopts a high-power engine to reserve power, has high utilization rate of effective power, large displacement of a hydraulic system, large torque of a transmission system and allowance configuration. The function increase has strong capacity expansion, such as: a communication and wireless control module can be additionally arranged to carry out remote control construction operation; the system can be upgraded into unmanned construction operation; and the expansion of the performance of other additional functions such as a fiber adding device can be added.

11. The equipment utilization rate is high: the equipment is used for paving operation in the whole process, and the equipment does not need to be wasted on transporting raw materials.

12. The performance function is stable and reliable: the equipment has compact and simple structure layout and scientific and reasonable design. The working performance is reliable and durable, and the use and the operation are easy, simple, convenient, multifunctional and intelligent. The use and maintenance cost is low, and the cost performance is high.

13. The popularization is strong: the method has the advantages of mature relevant basic technology, easy realization, high intelligence, simple and easy implementation and strong popularization.

In conclusion, the synchronous gravel seal paver and the construction method are easy, simple and convenient to operate, asphalt spraying gravel spreading precision is high and uniform, the spreading width is large, the adjustable range is flexible, continuous or intermittent construction can be achieved, construction efficiency is high, the synchronous gravel seal paver is suitable for construction under various working faces and environments, paving quality performance is superior and outstanding, the interlayer bonding force of paving layers is strong, performance is reliable, energy is saved, environment is protected, and the service life of the paved surface layers is far longer than that of traditional paving.

Drawings

The utility model is further illustrated by the following figures and examples, in which:

fig. 1 is a schematic view of the present invention.

Fig. 2 is a schematic structural diagram of the mineral aggregate conveying system.

Description of reference numerals:

1-a frame; 2-an internal combustion engine; 3-a transfer case; 4-a hydraulic system; 5, a gas path system; 6-circuitry;

7-control platform and control system; 8-pushing a roller; 9-a shoveling and pushing device; 10-a running gear; 11-a receiving hopper;

12-a mineral aggregate transport system;

121-mineral aggregate conveying device I; 122-mineral aggregate lifting means; 124-mineral aggregate conveying device IV;

125-mineral aggregate conveying and lifting device V; 126-a mineral aggregate lifting and conveying device VI;

127-a mineral aggregate conveying lifting conveying device VII;

13-a bitumen transfer system; 14-asphalt heating and heat preserving device; 15-a washing device; 16-a milling and brushing device;

17-a bitumen spraying device; 18-a gravel spreading device; 20-mineral aggregate distributor.

Detailed Description

The utility model is further described below with reference to the accompanying drawings:

example 1

As shown in figure 1, the synchronous chip seal paver comprises a frame-1, an internal combustion engine-2, a transfer case-3, a hydraulic system-4, an air circuit system-5, a circuit system-6, an operation platform and control system-7, a push roller-8, a push shovel device-9, a traveling device-10, a receiving hopper-11, a mineral aggregate transferring system-12, an asphalt transferring system-13, an asphalt heating and heat insulating device-14, a flushing device-15, a milling and brushing device-16, an asphalt spraying device-17, a chip spreading device-18, a dust removal device, a mineral aggregate distributor-20 and a generator set-21. The left side and the right side of the bottom of the frame-1 are symmetrically provided with a traveling device-10 in parallel, and a power assembly fixed in the rear part of the frame-1 above the traveling device-10 is provided with an internal combustion engine-2 and a transfer case-3 which provide sufficient power for various functional mechanisms of equipment and the like; the power input port of the transfer case-3 is connected with the power output port of the crankshaft of the internal combustion engine-2 in a transmission way, the power of the internal combustion engine-2 is reasonably distributed to functional parts by the specially designed transfer case-3, and each power output port of the transfer case-3 is connected with a hydraulic pump matched with each function in a transmission way so as to drive functional parts such as a hydraulic motor, a hydraulic oil cylinder and the like. The asphalt heating and heat-insulating device-14 is arranged right above the internal combustion engine-2 and the transfer case-3 and is fixed on the frame-1 by bolts. The front end of the frame-1 is provided with a pushing roller-8 for pushing the rear tire of the mineral aggregate conveying vehicle to move ahead synchronously with the mineral aggregate conveying vehicle. A receiving hopper-11 is hinged above the front part of the frame-1, and the receiving hopper is formed by two hopper components which are symmetrical left and right; the left side hopper and the right side hopper of the receiving hopper-11 can be flexibly opened and closed through a hydraulic oil cylinder to enable mineral aggregate to leak smoothly. The tail part of the machine frame-1 is provided with a gravel spreading device-18. A mineral aggregate transferring system-12 is arranged at the spatial position among the receiving hopper-11, the internal combustion engine-2, the lower side of the bottom of the transfer case-3, the rear side of the asphalt heating and heat preserving device-14 and the broken stone spreading device-18; the mineral aggregate transferring system-12 mainly comprises a I-level parallel conveying functional mechanism and a II-level lifting functional mechanism; a feed inlet of the mineral aggregate transferring system-12 is communicated with a discharge outlet of a receiving hopper at the bottom of the lower side of the receiving hopper-11; the mineral aggregate transferring system-12 is arranged above and communicated with the feeding hole of the gravel spreading device-18. The asphalt spraying device-17 is arranged at a spatial position between the lower part of the rear part of the machine frame-1 and the rear part of the walking device-10 and the front part of the outlet of the gravel spreading device-18. The control platform and the control system (control cabinet) -7 are arranged behind the machine frame-1 and at the front side or the rear side of the gravel spreading device-16.

Example 2

As shown in fig. 1 and fig. 2, the mineral aggregate transferring system 12 comprises mineral aggregate conveying devices i-121, mineral aggregate lifting devices-122 and mineral aggregate conveying devices iv-124, which respectively realize i-level parallel conveying, ii-level lifting conveying and iii-level parallel conveying to jointly transfer the mineral aggregate in the receiving hopper-11 to the gravel spreading device-18, measure and control the transferring feeding amount. The mineral aggregate conveying device I-121 is arranged on the lower side of the bottom of the receiving hopper-11, a feed inlet of the mineral aggregate conveying device I-11 (namely a feed inlet of the mineral aggregate transferring system) is communicated with a discharge outlet of the receiving hopper-11, and a discharge outlet of the mineral aggregate conveying device I-121 is communicated with a feed inlet of the mineral aggregate lifting device-12. The mineral aggregate lifting device-122 is arranged at a spatial position between the rear side of the receiving hopper-11 and the front side of the internal combustion engine-2 and is fixed on the frame-1; the mineral aggregate conveying device IV-124 is arranged below the discharge port of the mineral aggregate lifting device-122 and on the upper side or the lower side of the asphalt heating and heat insulating device-14 and is fixed on the frame-1, the discharge port of the mineral aggregate lifting device-122 is communicated with the feed port of the mineral aggregate conveying device IV-124, and the feed port of the gravel spreading device-18 is arranged below the discharge port of the mineral aggregate conveying device IV-124 (namely the discharge port of the mineral aggregate transferring system) and is communicated with the feed port.

As shown in FIG. 2, the first choice of the mineral aggregate conveying device I-121 is a chain scraper conveyor, which can also be a chain slat conveyor, a screw conveyor, a chain belt (combination of chain and belt) conveyor, or a belt conveyor. The driving sprocket shaft, or the screw shaft, or the belt roller shaft of the mineral aggregate conveying device I is in transmission connection with the speed reducer of the mineral aggregate conveying device I, the speed reducer of the mineral aggregate conveying device I is in transmission connection with the hydraulic motor of the mineral aggregate conveying device I, and the hydraulic motor of the mineral aggregate conveying device I is driven by the hydraulic pump which is connected with the transfer case in transmission connection and matched with the transfer case.

As shown in fig. 2, the mineral lifting device-122 is preferably a hopper lifter, and may also be a belt lifter with a large elevation angle, a chain belt (combination of chain and belt) lifter with a large elevation angle, or a scraper lifter. The driving chain wheel shaft or belt roller shaft of the mineral material lifting device is in transmission connection with a mineral material lifting device speed reducer, the mineral material lifting device speed reducer is in transmission connection with a mineral material lifting device hydraulic motor, and the mineral material lifting hydraulic motor is driven by a hydraulic pump matched with the mineral material lifting hydraulic motor and in transmission connection with a transfer case.

As shown in fig. 2, the mineral aggregate conveying device iv-124 is preferably a belt conveyor, which may be a chain scraper conveyor, a chain slat conveyor, a continuous (combination of chain and belt) conveyor, or a screw conveyor. The driving belt roller shaft, or the chain wheel shaft, or the screw shaft of the mineral aggregate conveying device IV is in transmission connection with a mineral aggregate conveying device IV speed reducer, the mineral aggregate conveying device IV speed reducer is in transmission connection with a mineral aggregate conveying device IV hydraulic motor, and the mineral aggregate conveying device IV hydraulic motor is driven by a hydraulic pump matched with the mineral aggregate conveying device IV and in transmission connection with the transfer case.

Example 3

As shown in figures 1 and 2, the mineral aggregate transferring system comprises mineral aggregate conveying and lifting devices V-125 and mineral aggregate conveying devices IV-124 which are used for jointly transferring mineral aggregates in the receiving hopper-11 to the gravel spreading device-18, metering and controlling the transferring feeding amount. The mineral aggregate conveying and lifting device V-125 is arranged at the lower side of the bottom of the receiving hopper-11, and the space position between the rear side of the receiving hopper-11 and the front side of the internal combustion engine-2 and is fixed on the frame-1, and the mineral aggregate conveying device IV-124 is arranged below the discharge port of the mineral aggregate conveying and lifting device V-125 and on the upper side or the lower side of the asphalt heating and heat preserving device and is fixed on the frame-1. The feed inlet of the mineral aggregate conveying and lifting device V-125 (namely the feed inlet of the mineral aggregate conveying system) is communicated with the discharge outlet of the receiving hopper-11; the discharge hole of the mineral aggregate conveying and lifting device V-125 is communicated with the feed hole of the mineral aggregate conveying device IV-124; a crushed stone spreading device-18 feeding hole is arranged under the discharge hole of the mineral aggregate conveying device IV-124 (namely the discharge hole of the mineral aggregate transferring system) and is communicated with the discharge hole.

As shown in fig. 2, the mineral aggregate conveying and lifting device V-125 comprises a I-level parallel conveying function and a II-level lifting function at the same time and is fixed on a rack-1, and the mineral aggregate conveying device IV-124 realizes a III-level parallel conveying function. The mineral aggregate conveying and lifting device V-125 is preferably a hopper type lifting conveyor, and can also be either a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor. The V-shaped speed reducer of the mineral aggregate conveying and lifting device is in transmission connection with a V-shaped driving chain wheel shaft or a belt roller shaft of the mineral aggregate conveying and lifting device, the V-shaped speed reducer of the mineral aggregate conveying and lifting device is in transmission connection with a V-shaped hydraulic motor of the mineral aggregate conveying and lifting device, and the V-shaped hydraulic motor of the mineral aggregate conveying and lifting device is driven by a hydraulic pump matched with the V-shaped hydraulic motor in transmission connection with a transfer case.

Example 4

As shown in figures 1 and 2, the mineral aggregate transferring system comprises mineral aggregate conveying devices I-121 and mineral aggregate lifting conveying devices VI-126, so that mineral aggregates in the receiving hopper-11 are transferred to the gravel spreading device-18 together, and the transferring feeding amount is metered and controlled. The mineral aggregate conveying device I-121 is arranged on the lower side of the bottom of the receiving hopper-11, a feed port of the mineral aggregate conveying device I-121 (namely a feed port of the mineral aggregate transferring system) is communicated with a discharge port of the receiving hopper-11, and a discharge port of the mineral aggregate conveying device I-121 is communicated with a feed port of the mineral aggregate lifting device VI-126. The mineral aggregate lifting and conveying device VI-126 is arranged at the space position between the rear side of the receiving hopper-11 and the front side of the internal combustion engine-2 and the upper side or the lower side of the asphalt heating and heat preserving device-14. A crushed stone spreading device-18 feeding hole is arranged under the discharge hole of the mineral aggregate lifting and conveying device VI-126 (namely the discharge hole of the mineral aggregate transferring and conveying system) and is communicated with the discharge hole.

In the scheme, as shown in fig. 2, the mineral aggregate conveying device I-121 achieves a I-level parallel conveying function, and the mineral aggregate lifting and conveying device VI-126 simultaneously comprises a II-level lifting function and a III-level parallel conveying function and is fixed on the rack-1. The ore material lifting and conveying device VI-126 is preferably a hopper type lifting conveyor, and can also be a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor. The driving sprocket shaft or the belt roller shaft of the mineral aggregate lifting and conveying device VI is in transmission connection with the speed reducer of the mineral aggregate lifting and conveying device VI, the speed reducer of the mineral aggregate lifting and conveying device VI is in transmission connection with the hydraulic motor of the mineral aggregate lifting and conveying device VI, and the hydraulic motor of the mineral aggregate lifting and conveying device VI is driven by the hydraulic pump which is connected with the transfer case in transmission connection and matched with the hydraulic motor.

Example 5

As shown in figures 1 and 2, the mineral aggregate transferring system-12 comprises mineral aggregate transferring lifting conveying devices VII-127 to transfer mineral aggregates in the receiving hopper-11 to the gravel spreading device-18, and the transferring feeding amount is metered and controlled. The mineral aggregate conveying, lifting and conveying device VII-127 is arranged at the lower side of the bottom of the receiving hopper-11, the space position between the rear side of the receiving hopper-11 and the front side of the internal combustion engine-2 and the upper side or the lower side of the asphalt heating and heat preserving device and is fixed on the frame-1. The feed inlet of the mineral aggregate conveying and lifting conveying device VII-127 (namely the feed inlet of the mineral aggregate transferring system) is communicated with the discharge outlet of the receiving hopper-11, and the feed inlet of the gravel spreading device-18 is arranged under the discharge outlet of the mineral aggregate conveying and lifting conveying device VII-127 (namely the discharge outlet of the mineral aggregate transferring system) and is communicated with the discharge outlet.

As shown in figure 2, the mineral aggregate conveying, lifting and conveying device VII-127 simultaneously comprises a I-level parallel conveying function, a II-level lifting function and a III-level parallel conveying function and is in a step type. The mineral aggregate conveying, lifting and conveying device VII-127 is preferably a hopper type lifting conveyor, and can also be a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor. The driving chain wheel shaft or the belt roller shaft of the mineral aggregate conveying and lifting conveying device VII is in transmission connection with a mineral aggregate conveying and lifting conveying device VII speed reducer, the mineral aggregate conveying and lifting conveying device VII speed reducer is in transmission connection with a mineral aggregate conveying and lifting conveying device VII hydraulic motor, and the mineral aggregate conveying and lifting conveying device VII hydraulic motor is driven by a hydraulic pump matched with the mineral aggregate conveying and lifting conveying device VII hydraulic motor in transmission connection with a transfer case.

Example 6

As shown in fig. 1 and 2, the mineral aggregate transferring system-12 is designed with a mineral aggregate metering device to implement precise regulation and control and metering of mineral aggregate conveying amount. Metering sensors are respectively arranged in the I-level parallel conveying machine, the II-level lifting conveying machine and the III-level parallel conveying machine, and the mineral aggregate conveying device is matched with and coordinates the conveying capacity and speed of a mineral aggregate conveying system through the displacement change or the rotating speed regulation of a variable hydraulic motor or a variable hydraulic pump. The rotation speed is regulated steplessly, and the control of changing the feeding amount of the mineral aggregate conveying system and the metering precision is completed.

Example 7

As shown in figure 1, the synchronous chip sealer paver also comprises a mineral aggregate distributor-20, wherein the mineral aggregate distributor-20 is arranged on a discharge port of a mineral aggregate transferring system-12, or is arranged on a feed port of a chip spreading device-18, or is separately arranged between the discharge port of the mineral aggregate transferring system-12 and the feed port of the chip spreading device-18. And the discharge hole of the mineral aggregate transferring system, the mineral aggregate distributor and the feed hole of the gravel spreading device are communicated. Because the mineral aggregate spreading devices with different structural forms are selected and matched, the requirement on the distribution is different; when a fixed mechanical folding type mineral aggregate spreading device is usually selected for small-width (single-width pavement) spreading, a discharge port of a mineral aggregate conveying device directly feeds into the mineral aggregate spreading device; when the telescopic mineral aggregate spreading device is selected, mineral aggregates are respectively conveyed into a left mineral aggregate distributing and distributing groove and a right mineral aggregate distributing and distributing groove; particularly, when the pavement is spread in a large width and an over width (a plurality of pavements), the mineral aggregate must be respectively conveyed to left and right spiral distributing material grooves in corresponding mineral aggregate spreading devices. Therefore, the mineral aggregate distributor-20 is designed, so that the mineral aggregate can be effectively distributed when the mineral aggregate distributor is fed into the broken stone spreading device through the distributor-20, and the continuous and stable spreading construction operation is ensured.

Example 8

As shown in figure 1, the asphalt heating and heat preserving device-14 comprises an asphalt tank, a liquid level sensor, a burner, a combustion chamber, a chimney, an asphalt pipeline, a valve, heat conducting oil, a heat conducting oil pipe, a temperature sensor, a temperature controller, a thermometer, a pressure gauge, a pressure sensor, a pressure controller and the like. The asphalt heating and heat-preserving device is used for storing enough asphalt and preserving and heating the asphalt; the asphalt heating and heat insulating device is arranged above the internal combustion engine-2 and the transfer case-3 and is fixed on the frame-1 by bolts.

Example 9

As shown in figure 1, the asphalt transferring system-13 comprises a feeding asphalt pump I, an asphalt spraying pump, an asphalt conveying pipeline, an asphalt flowmeter, an asphalt pipeline valve, an asphalt multi-way flow dividing valve, a thermometer, a pressure gauge, a temperature sensor, a temperature controller, a pressure sensor and a pressure controller. Most parts of the asphalt transferring system-13 are arranged on both sides of the mineral aggregate lifting device-122 and the rear side of the asphalt heating and heat preserving device-14. The feeding asphalt pump I and the asphalt spraying pump are arranged on two sides of the lower part of the mineral aggregate lifting device-122 and are fixed on the frame-1, and inlets of the feeding asphalt pump I are respectively fixed on two sides of the lower part of the center of the frame-1. An inlet and an outlet of the feeding asphalt pump I are respectively connected with an asphalt outlet of the asphalt conveying vehicle and an inlet pipeline of the asphalt heating and heat insulating device, and are used for conveying asphalt on the asphalt conveying vehicle into the asphalt heating and heat insulating device-14; the inlet and outlet of the asphalt spraying pump are respectively connected with the asphalt heating and heat-insulating device-14, the valve, the asphalt flow meter, the asphalt pressure gauge, the inlet of the asphalt spraying device-17 and other pipelines, and the asphalt is conveyed to the asphalt spraying device-17.

As shown in fig. 1, the asphalt transferring system-13 further includes a feeding asphalt pump ii-133, and the feeding asphalt pump ii-133 is disposed at the lower portion of the center of the rear side of the crushed stone spreading device and fixed on the frame by using a cantilever beam structure. The inlet and the outlet of the feeding asphalt pump II-133 are respectively connected with an asphalt outlet of the asphalt conveying vehicle and an inlet pipeline of the asphalt heating and heat preserving device-14, and the feeding asphalt pump II-133 is used for conveying asphalt on the asphalt conveying vehicle into the asphalt heating and heat preserving device-14.

As shown in figure 1, the asphalt transferring system-13 is provided with an asphalt metering device which comprises an asphalt flowmeter, an asphalt pressure sensor and an asphalt pump rotating speed sensor. The feeding asphalt pump I-131 and the asphalt spraying pump 132 adopt a variable asphalt pump or a variable hydraulic pump and a variable hydraulic motor; the delivery flow and the pressure of the asphalt delivery system are cooperatively and coordinately controlled through the displacement change or the rotating speed regulation of the variable hydraulic motor or the variable hydraulic pump and the opening and closing degree of the valve of the asphalt pipeline. The control of the asphalt spraying amount and the metering precision of the asphalt conveying system is finished. The feed asphalt pump I-131 and asphalt spray pump 132 may also be driven by electric or variable frequency electric motors, preferably hydraulic motors.

Example 10

As shown in figure 1, the synchronous chip seal paver also comprises a movable feeding asphalt pump III and a movable water supply pump. When water and asphalt are transferred to the water tank and the asphalt heating and heat insulating device, a submersible pump (an asphalt pump and a water pump) can be independently adopted to be placed in a transport vehicle tank, and an outlet pipeline of the submersible pump is connected with the asphalt heating and heat insulating device and an inlet of the water tank to transfer the asphalt and the water. The mobile pump is powered by the generator set-21 and is controlled manually or intelligently by the control platform.

Example 11

The pipeline bracket is arranged on the two sides and the rear side of the synchronous chip seal paver, the pipeline is suspended by the rope, and the rope suspension end can slide back and forth on the pipeline bracket. When water and asphalt in the asphalt truck are transferred to an asphalt buffer tank in a synchronous chip sealer paver, the asphalt conveying pipeline is hung on a pipeline bracket. The pipeline is supported in such a way, and the dragging effect on the pipeline caused by asynchronous stopping and starting of the equipment room is eliminated; when the speed of the equipment is different in the walking process, the dragging effect on the pipeline is buffered. Ensure the normal work of the conveying pipeline.

Example 12

As shown in FIG. 1, the running gear-10 is preferably a crawler-type running gear; or a wheel type walking mechanism, or a crawler and wheel type combined walking mechanism, namely a front wheel rear crawler belt. The crawler-type traveling mechanism driving chain wheel or the wheel-type traveling mechanism wheel drum is in transmission connection with a traveling speed reducer of the traveling device-10; the walking speed reducer is connected with a walking hydraulic motor of the walking device-10 in a transmission way and is driven by a hydraulic motor of the walking device driven by a walking hydraulic pump matched with the transfer case in a transmission way. The hydraulic system of the walking device-10 is a closed system. The walking variable hydraulic motor, the variable hydraulic pump and the rotating speed sensor are selected to realize speed regulation. A hydraulic brake device is adopted.

Example 13

As shown in fig. 1, the push roller-8 is arranged at the front end of the frame-1 of the synchronous chip sealer paver, and when a dump truck discharges materials to the receiving hopper-11, the push roller-8 pushes the rear tires of the dump truck to realize synchronous advance.

Example 14

As shown in figure 1, the receiving hopper-11 is a receiving hopper formed by two hopper parts which are symmetrical left and right, and is designed to have opening and closing functions. The material receiving hopper-11 is hinged above the front part of the frame-1 and is opened and closed through a hydraulic oil cylinder to ensure that mineral materials are smoothly leaked.

Example 15

As shown in figure 1, the hydraulic system-4 is mainly formed by connecting a hydraulic pump which is connected with a power output port of the transfer case-3 and has matched functions, executing components such as a hydraulic motor, a hydraulic oil cylinder and the like with integrated valve blocks, functional valve blocks, sensors and hydraulic pipelines.

Example 16

As shown in fig. 1, the air path system-5 is formed by connecting an air compressor device, an air storage tank, an air cylinder and other execution components, an integrated valve block, a functional valve block, a sensor, an air pipe and the like. An air compressor is connected with the power take-off of the engine-2 in a transmission way to provide compressed air. The control system on the control platform controls the air cylinder in the punching and milling device-15 so as to realize the opening and closing of the water spray head; an air cylinder in the asphalt spraying device-17 further realizes the opening and closing of an asphalt spray head; and controlling the opening and closing of a valve in the asphalt transferring system-13, the opening and closing of a valve in the waterway transferring system and the like.

Example 17

As shown in figure 1, a control platform and control system-7 (comprising a control module cabinet) and an electric control cabinet of the generator set-21 are arranged at the rear part of a frame-1, and part of the electric control module, a hydraulic module, a gas circuit module and the circuit system-6 are distributed at proper positions in different spaces of the body of the synchronous chip seal paver. The control platform and the control system-7 carry out intelligent control and management on all functions of the synchronous chip seal paver.

Example 18

The fiber agent adding system comprises a fiber conveying device and a fiber adding executing device. Realize the addition of fiber in the asphalt spraying and gravel spreading operation engineering.

Example 19

As shown in FIG. 1, a crushed stone spreading device-18 is provided at the rear of the frame-1. Preferably select for use telescopic rubble dispensing device to realize the even accurate dispensing of mineral aggregate.

Example 20

As shown in FIG. 1, a synchronous chip breaker paver also includes a "dry" pretreatment system, namely a minimally invasive milling and brushing apparatus-16. The minimally invasive milling and brushing device is arranged between the lower part of the rear part of the frame-1, the rear part of the walking device-10 and the front part of the asphalt spraying device-17. Used for cleaning the road surface or carrying out minimally invasive finish milling and planing on the road surface. The pavement cleanliness of the to-be-constructed pavement is improved, the adhesion between the paving surface layers of the synchronous gravel sealing layer is enhanced, the paving quality is improved, and the occurrence of pavement diseases is reduced.

Example 21

As shown in fig. 1, the synchronous chip sealer paver further comprises a 'wet' pretreatment system, namely a minimally invasive impact milling device-15. The minimally invasive punching and milling device-15 is arranged at a space position between the lower part of the rear part of the rack-1, the rear part of the walking device-10 and the front part of the asphalt spraying device-17. And carrying out minimally invasive punching and milling on the road surface layer by adopting a plurality of high-pressure water flows. The pavement cleanliness of the to-be-constructed pavement is improved, the temperature of the pavement is improved, and the adhesion between the paving surface layers of the synchronous gravel seal layer is enhanced, so that the paving quality is improved, and the occurrence of pavement diseases is reduced.

Example 22

As shown in fig. 1, the synchronous chip sealer paver further comprises a push shovel device-9. The shovel device-9 is arranged below the front part of the frame-1 and at the front side of the walking device-10. The aim of pushing the scattered mineral aggregate and other useless materials to the two sides of the pavement to be constructed is achieved.

Example 23

The synchronous broken stone seal paver also comprises a dust removal device, wherein the dust removal device is used for collecting dust generated in the broken stone spreading process, dust generated in the operation of a minimally invasive milling and brushing device-16 and oil smoke generated in the asphalt spraying and sweeping process. The dust removing device comprises a dust hood, an exhaust fan, a dust filtering device and a dust hood lifting device. The dust hood surrounds the discharge hole of the gravel spreading device-18, the milling and brushing device-16 and the asphalt spraying device-17 and can be adjusted up and down, the dust hood keeps a small distance from the pavement in the gravel spreading operation process so as not to influence the pavement, and otherwise, the dust hood is lifted to be as far away from the pavement as possible. The dust hood is connected with the exhaust fan inlet pipeline, and the dust filtering device is connected with the exhaust fan outlet pipeline.

In conclusion, compared with the traditional synchronous chip sealer vehicle, the sprayed and spread pavement quality is obviously improved. The excellent performance is shown as follows: the process procedures of receiving materials, carrying out minimally invasive pretreatment, namely, carrying out wet-type minimally invasive punching and milling dry-type minimally invasive milling and sweeping, spraying asphalt, spreading fibers, spreading broken stones, removing dust and the like can be simultaneously integrated into a whole to complete the paving construction operation at one time. The system has the function of continuous construction operation or intermittent construction operation without other special supporting equipment. The innovative design of 'dry' and 'wet' minimally invasive pretreatment devices to implement minimally invasive punching and milling and minimally invasive milling and brushing processes perfectly realizes the effect of remarkably enhancing the interlayer adhesive force of the pavement. Easy and convenient material receiving, simple and intelligent control, skillfully improved yield in unit time and reduced production cost. The problems of longitudinal and transverse joints and stub bars are effectively solved, and the phenomenon of different paving qualities appears in the same construction section due to the color difference phenomenon of pavement appearing in construction caused by different equipment and manipulators. The construction efficiency of single equipment is improved by times, the yield in unit time is large, the spraying and spreading width range is large, and the width setting and changing are flexible. The precision of asphalt spraying and broken stone spreading is high, the interlaminar adhesive force is strong, the spreading quality is excellent and stable, the pavement diseases are reduced, the energy is saved, the environment is protected, and the service life of the pavement is prolonged. The equipment and the construction method are suitable for construction in various working surfaces and environments. The equipment utilization rate is high, and the whole process is used for paving construction operation without wasting transportation raw materials. The device has compact, scientific and reasonable structural layout, reliable working performance, low use and maintenance cost, high cost performance and strong popularization. The peak reaching by carbon and the neutralization by carbon are met.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and all the simple modifications, changes, equivalent structural changes and construction method changes made by the technical essence of the present invention are still within the protection scope of the technical solution and method of the present invention.

Claims (10)

1. A synchronous macadam seal coat paver is characterized by comprising a rack (1), an internal combustion engine (2), a transfer case (3), a traveling device (10), a receiving hopper (11), a mineral aggregate transferring system (12), an asphalt transferring system (13), a hydraulic system (4), an asphalt heating and heat insulating device (14), an asphalt spraying device (17) and a macadam spreading device (18); the left and the right of the lower part of the frame (1) are provided with traveling devices (10), the internal combustion engine (2) is fixed in the rear upper part of the traveling devices (10) and the rear part of the frame (1), the receiving hopper (11) is arranged above the front part of the frame (1), the mineral aggregate transferring system (12) comprises a I-level parallel conveying function and a II-level lifting function, the discharge hole of the receiving hopper (11) is communicated with the feed hole of the mineral aggregate transferring system (12), the asphalt heating and heat-preserving device (14) is arranged above the internal combustion engine (2), the asphalt spraying device (17) is arranged below the rear part of the frame (1) and behind the traveling device (10), the crushed stone spreading device (18) is arranged at the tail part of the rack (1), and a discharge hole of the mineral aggregate transferring system (12) is arranged above a feed hole of the crushed stone spreading device (18) and communicated with the discharge hole.

2. The synchronous chip seal paver of claim 1, characterized in that the mineral aggregate transfer system (12) comprises a mineral aggregate conveying device I (121), a mineral aggregate lifting device (122) and a mineral aggregate conveying device IV (124), and the mineral aggregate in the receiving hopper (11) is transferred to the chip spreading device (18); the mineral aggregate conveying device I is arranged at the lower side of the receiving hopper, a feed inlet of the mineral aggregate conveying device I (121), namely the feed inlet of the mineral aggregate transferring system is communicated with the discharge outlet of the receiving hopper (11), the discharge outlet of the mineral aggregate conveying device I (121) is communicated with the feed inlet of the mineral aggregate lifting device (122), the mineral aggregate lifting device (122) is arranged between the rear side of the receiving hopper (11) and the front side of the internal combustion engine (2), the mineral aggregate conveying device IV (124) is arranged on the upper side or the lower side of the asphalt heating and heat preserving device (14), the discharge hole of the mineral aggregate lifting device (122) is arranged above and communicated with the feed hole of the mineral aggregate conveying device IV (124), the discharge hole of the mineral aggregate conveying device IV (124), namely a discharge hole of the mineral aggregate transferring system is arranged above and communicated with a feed hole of the gravel spreading device (18).

3. The synchronous chip seal paver of claim 2 characterized in that the mineral aggregate conveying device I (121) is a chain scraper conveyor, or a chain slat conveyor, or a screw conveyor, or a chain belt conveyor, or a belt conveyor, the mineral aggregate lifting device (122) is a hopper type elevator, or a belt type elevator, or a chain belt type elevator, or a scraper type elevator, and the mineral aggregate conveying device IV (124) is a belt conveyor, or a chain scraper conveyor, or a chain slat conveyor, or a chain belt conveyor, or a screw conveyor.

4. The synchronous chip seal paver of claim 1, characterized in that the mineral aggregate transfer system (12) comprises a mineral aggregate conveying and lifting device V (125) and a mineral aggregate conveying device IV (124) for transferring mineral aggregate in the receiving hopper (11) to the chip spreading device (18); the mineral aggregate conveying and lifting device V (125) is arranged between the lower side of the receiving hopper (11), the rear side of the receiving hopper (11) and the front side of the internal combustion engine (2), and a feed port of the mineral aggregate conveying and lifting device V (125), namely a feed port of a mineral aggregate transferring system, is communicated with a discharge port of the receiving hopper (11); the ore material conveying device IV (124) is arranged on the upper side or the lower side of the asphalt heating and heat insulating device (14), a discharge hole of the ore material conveying and lifting device V (125) is arranged above a feed hole of the ore material conveying device IV (124) and communicated with the feed hole of the ore material conveying device V (124), and a discharge hole of the ore material conveying device IV (124), namely a discharge hole of the ore material transferring system, is arranged above a feed hole of the gravel spreading device (18) and communicated with the feed hole of the gravel spreading device.

5. The synchronous chip seal paver of claim 1 or 4, characterized in that the mineral aggregate conveying and lifting device V (125) comprises a level I parallel conveying and a level II lifting function, and the mineral aggregate conveying device IV (124) realizes the level III parallel conveying function; the mineral aggregate conveying and lifting device V (125) is a hopper type lifting conveyor, a belt type lifting conveyor, a lifting scraper conveyor or a chain belt type lifting conveyor.

6. The synchronous chip seal paver of claim 1, characterized in that the mineral aggregate transfer system (12) comprises a mineral aggregate conveying device I (121) and a mineral aggregate lifting and conveying device VI (126) for transferring the mineral aggregate in the receiving hopper (11) to the chip spreading device (18); the mineral aggregate conveying device I (121) is arranged on the lower side of the receiving hopper, a feed inlet of the mineral aggregate conveying device I (121), namely a feed inlet of the mineral aggregate transferring system, is communicated with a discharge outlet of the receiving hopper (11), and a discharge outlet of the mineral aggregate conveying device I (121) is communicated with a feed inlet of the mineral aggregate lifting conveying device VI (126); the mineral aggregate lifting and conveying device VI (126) is arranged between the rear side of the receiving hopper (11) and the front side of the internal combustion engine and on the upper side or the lower side of the asphalt heating and heat insulating device (14), and a discharge hole of the mineral aggregate lifting and conveying device VI (126), namely a discharge hole of a mineral aggregate transferring system, is arranged above a feed hole of the gravel spreading device (18) and communicated with the feed hole.

7. The synchronous chip seal paver of claim 1 or 6 wherein the mineral aggregate conveyor i (121) performs a level i parallel conveying function, and the mineral aggregate lifting conveyor vi (126) includes a level ii lifting and level iii parallel conveying function; the mineral aggregate lifting and conveying device VI (126) is a hopper type lifting conveyor, a belt type lifting conveyor, a lifting scraper conveyor or a chain belt type lifting conveyor.

8. The synchronous chip seal paver of claim 1 characterized in that the mineral aggregate transfer system (12) comprises a mineral aggregate transfer lifting conveyor vii (127) effecting transfer of mineral aggregate in the receiving hopper (11) into the chip spreading device (18); the mineral aggregate conveying, lifting and conveying device VII (127) is arranged on the lower side of the receiving hopper (11), between the rear side of the receiving hopper (11) and the front side of the internal combustion engine (2) and on the upper side or the lower side of the asphalt heating and heat preserving device (14); the feed inlet of the mineral aggregate conveying and lifting conveying device VII (127), namely the feed inlet of the mineral aggregate transferring system, is communicated with the discharge outlet of the receiving hopper (11), and the discharge outlet of the mineral aggregate conveying and lifting conveying device VII (127), namely the discharge outlet of the mineral aggregate transferring system, is arranged above the feed inlet of the gravel dispensing device (18) and is communicated with the feed inlet.

9. The synchronous chip seal paver of claim 1 characterized in that the mineral aggregate conveying lifting conveyor VII (127) comprises a class I parallel conveying function, a class II lifting function and a class III parallel conveying function, and the mineral aggregate conveying lifting conveyor VII (127) is a hopper type lifting conveyor, a chain belt type lifting conveyor, a belt type lifting conveyor or a lifting scraper conveyor.

10. The synchronous chip sealer paver of claim 1, characterized in that the running gear (10) is hydraulically driven.

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