CN220251010U - Screed posture monitoring structure of paver - Google Patents

Abstract

The utility model discloses a screed posture monitoring structure of a paver, and relates to the technical field of screeds. The screed posture monitoring structure of the paver is characterized in that a mounting table is mounted on the screed, a transverse slope sensor is detachably mounted on the top surface of the mounting table, and the transverse slope sensor is used for monitoring the inclination state and the gradient value of the screed; the fixed hook plate is arranged on the mounting table, is assembled to be arranged on the side surface of the mounting table in a vertical sliding mode, and is fixed through the clamping assembly on the fixed hook plate so that the fixed hook plate can be hooked on the surface of the transverse slope sensor. According to the utility model, through arranging the fixing hook plate and the clamping assembly, the mounting and fixing of the transverse slope sensor can be realized through clamping, and the bolts are not required to be screwed for fixing by using a dismounting tool, so that the mounting efficiency is improved, and the problems that the dismounting process is troublesome and the dismounting time is more because the bolts are fixed on the screed plate and the dismounting tool is required are solved.

Description

Screed posture monitoring structure of paver

Technical Field

The utility model relates to the technical field of screeds, in particular to a screed posture monitoring structure of a paver.

Background

The paver uniformly paves asphalt mixture on a road base layer and performs primary compaction and leveling, and the paver consists of a traction part, a paving part, a compaction part, a ironing part and the like, wherein the traction part comprises a frame, a power device, a traveling device, a hopper, a material door, a scraper conveyor, a spiral paver, a cab and the like, and the later comprises a traction arm, a compaction mechanism and an ironing device, and the paving part performs ironing and paving operation on paving materials paved on a road surface through the ironing plate in the paving operation process.

The transverse slope sensor is arranged on the common screed and used for monitoring the inclination states and the gradient values of the screed and the machine body, and then the detected information is transmitted to the driving control panel, so that the posture of the screed of the paver can be calibrated.

At present, a transverse slope sensor is fixed on a screed plate through a plurality of bolts, so that the operation is complex, and when the transverse slope sensor is installed and maintained, the transverse slope sensor needs to be disassembled and assembled through a disassembly tool, so that the disassembly process is troublesome, and the time consumed in disassembly is more.

Disclosure of Invention

The utility model aims to provide a screed posture monitoring structure of a paver, which aims to solve the problems that the disassembly and assembly process is troublesome and the time consumed for disassembly is more because the screed posture monitoring structure is required to be disassembled and assembled by a disassembly tool.

The utility model is realized in such a way that the screed posture monitoring structure of the paver comprises an installation table installed on the screed, wherein a transverse slope sensor is detachably installed on the top surface of the installation table, and the transverse slope sensor is used for monitoring the inclination state and the gradient value of the screed; the fixed hook plate is arranged on the mounting table, is assembled to be arranged on the side surface of the mounting table in a vertical sliding mode, and is fixed through the clamping assembly on the fixed hook plate so that the fixed hook plate can be hooked on the surface of the transverse slope sensor.

Further, the spout has been seted up to the side of mount table, fixed hook plate slides and sets up the inside wall at the spout, fixed hook plate sets up to L shape, the side integrated into one piece of fixed hook plate has the guide bar, the spacing groove that can with guide bar movable phase adaptation has all been seted up to the inside both sides of spout.

Further, the joint subassembly includes arm-tie and bellying, the recess has been seted up to the side of mount table, the recess is linked together with the spout, arm-tie swing joint is at the inside wall of recess, the arm-tie sets up to the convexity, the top of arm-tie is connected with the one end of fixed collude the board through the connecting axle, bellying integrated into one piece is in one side of arm-tie, bellying closely laminates with the inboard top of recess, the bellying sets up to the arc, the arc wall has been seted up to the inside wall of recess.

Further, a slot is formed in one side, far away from the fixed hook plate, of the pulling plate, an outwards inclined plate is fixedly arranged on the inner side wall of the slot, and the inclined plate is used for holding the pulling plate by hands and then pulling the pulling plate to move.

Further, the side of mount table is provided with the cardboard through the dead lever, the dead lever is fixed to be set up at the surface of mount table, the dead lever sets up to T shape, the cardboard is closely cup jointed at the surface of dead lever, the fixed surface of arm-tie is provided with takes the board, take the board and set up to L shape, the cardboard is taken and is put the surface of board, cardboard and the surface swing joint of arm-tie.

Further, a positioning block is fixedly arranged on the surface of the fixed hook plate, a positioning groove which can be matched with the positioning block is formed in the surface of the transverse slope sensor, and the positioning block is movably inserted into the inner side wall of the positioning groove.

Further, a guide groove is formed in the opening of the positioning groove, the guide groove is obliquely formed, and the guide groove is used for guiding the positioning block during insertion.

Compared with the prior art, the screed posture monitoring structure of the paver has the following beneficial effects:

through setting up fixed board and joint subassembly of colluding, place the top of mount table with the sideslip sensor, afterwards with fixed board that colludes down slide, make fixed surface contact of colluding board and sideslip sensor, afterwards fix the fixed board that colludes through joint subassembly, make fixed surface in close contact with of colluding board and sideslip sensor, it is fixed to install the sideslip sensor through the centre gripping formula, it is fixed to have reached, need not use assembly and disassembly tools to twist the bolt, thereby improve the advantage of installation effectiveness, the need is dismantled and assembled through assembly and disassembly tools, the relatively trouble of dismouting process has been led to, the problem that the time consumed of dismantlement is more has been solved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the surface structure of the mounting table according to the present utility model;

FIG. 3 is a schematic view of a clamping assembly according to the present utility model;

FIG. 4 is a schematic diagram of a positioning slot according to the present utility model.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The implementation of the present utility model will be described in detail below with reference to specific embodiments.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present utility model, it should be understood that, if there is an azimuth or positional relationship indicated by terms such as "upper", "lower", "left", "right", etc., based on the azimuth or positional relationship shown in the drawings, it is only for convenience of describing the present utility model and simplifying the description, but it is not indicated or implied that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus terms describing the positional relationship in the drawings are merely illustrative and should not be construed as limitations of the present patent, and specific meanings of the terms described above may be understood by those skilled in the art according to specific circumstances.

Referring to fig. 1-4, a preferred embodiment of the present utility model is provided.

The screed posture monitoring structure of the paver comprises a mounting table 1 mounted on the screed, wherein a transverse slope sensor 2 is detachably mounted on the top surface of the mounting table, and the transverse slope sensor 2 is used for monitoring the inclination state and the gradient value of the screed; the fixed hook plate 3 is arranged on the mounting table 1, is assembled to be arranged on the side surface of the mounting table 1 in a vertical sliding way, and is fixed through a clamping assembly on the fixed hook plate so as to enable the fixed hook plate to be hooked on the surface of the transverse slope sensor 2.

Specifically, spout 4 has been seted up to the side of mount table 1, and fixed hook plate 3 slides and sets up the inside wall at spout 4, and fixed hook plate 3 sets up to the L shape, and fixed side integrated into one piece that colludes plate 3 has guide bar 5, and the spacing groove that can with guide bar 5 movable looks adaptation has all been seted up to the inside both sides of spout 4.

In this embodiment, the fixed hook plate 3 moves along the inner side wall of the chute 4, the chute 4 guides the fixed hook plate 3, the fixed hook plate 3 drives the guide rod 5 to move along the inner side wall of the limit groove, and the limit groove and the guide rod 5 can guide and limit the fixed hook plate 3 in the chute 4.

Specifically, the joint subassembly includes arm-tie 6 and bellying 7, recess 8 has been seted up to the side of mount table 1, recess 8 is linked together with spout 4, arm-tie 6 swing joint is at the inside wall of recess 8, arm-tie 6 sets up to the convexity, the top of arm-tie 6 is connected with the one end of fixed hook plate 3 through the connecting axle, bellying 7 integrated into one piece is in one side of arm-tie 6, bellying 7 closely laminates with the inboard top of recess 8, bellying 7 sets up to the arc, the arc wall has been seted up to the inside wall of recess 8.

In this embodiment, with fixed hook plate 3 downward pulling, fixed hook plate 3 drives arm-tie 6 motion simultaneously, fixed hook plate 3 moves to with the surface contact back of sideslip sensor 2, rotate arm-tie 6 around the connecting axle, make arm-tie 6 enter into recess 8, drive bellying 7 simultaneously along the arc wall enter into recess 8 in, bellying 7 can extrude recess 8's inside wall, make bellying 7 closely laminate with recess 8's inside wall, make arm-tie 6 joint in recess 8, can pull fixed hook plate 3 simultaneously and the inseparable laminating of surface of sideslip sensor 2, thereby can be spacing to sideslip sensor 2 centre gripping, accomplish the installation to sideslip sensor 2.

Specifically, a slot 9 is formed in one side, far away from the fixed hook plate 3, of the pull plate 6, an inclined plate 10 inclined outwards is fixedly arranged on the inner side wall of the slot 9, and the inclined plate 10 is used for holding the pull plate 6 by hands and pulling the pull plate to move.

In this embodiment, when the lateral slope sensor 2 is disassembled, the hand is inserted into the slot 9 and then contacts with the sloping plate 10, and the sloping plate 10 is pulled by force to drive the pulling plate 6 to rotate around the connecting shaft, so that the pulling plate 6 is pulled to rotate conveniently.

Specifically, the side of mount table 1 is provided with cardboard 12 through dead lever 11, and dead lever 11 is fixed to be set up at the surface of mount table 1, and dead lever 11 sets up to the T shape, and cardboard 12 closely cup joints at the surface of dead lever 11, and the fixed surface of arm-tie 6 is provided with and takes board 13, takes board 13 to set up to the L shape, and cardboard 12 takes the surface of putting board 13, cardboard 12 and the surface swing joint of arm-tie 6.

In this embodiment, after installing the sensor 2 of the horizontal slope, rotate the cardboard 12 around the dead lever 11, make the cardboard 12 put on the surface of putting the board 13, simultaneously with the surface contact of arm-tie 6, the cardboard 12 can be with arm-tie 6 spacing in recess 8, avoids arm-tie 6 to break away from recess 8, improves the steadiness to the sensor 2 of the horizontal slope is fixed.

Specifically, the surface of the fixed hook plate 3 is fixedly provided with a positioning block 14, the surface of the transverse slope sensor 2 is provided with a positioning groove 15 which can be matched with the positioning block 14, and the positioning block 14 is movably inserted into the inner side wall of the positioning groove 15.

In this embodiment, the fixed hook plate 3 moves downward along the inner side wall of the chute 4, so that the fixed hook plate 3 drives the positioning block 14 to be inserted into the positioning slot 15, thereby positioning the transverse slope sensor 2 and avoiding fixed offset.

Specifically, the opening of the positioning groove 15 is provided with a guiding groove 16, the guiding groove 16 is obliquely provided, and the guiding groove 16 is used for guiding the positioning block 14 during insertion.

In this embodiment, when the fixed hook plate 3 drives the positioning block 14 to be inserted into the positioning groove 15, the transverse slope sensor 2 is moved to align the positioning groove 15 with the positioning block 14, then the positioning block 14 can be inserted into the positioning groove 15 along the inclined surface of the guiding groove 16, and the guiding groove 16 can guide the positioning block 14, so that the positioning block 14 is convenient to be inserted into the positioning groove 15.

When the paver is used, the transverse slope sensor 2 is arranged on the screed, and when the screed is used for carrying out screed paving operation on paving materials paved on a road surface, the transverse slope sensor 2 monitors the inclination states and gradient values of the screed and the machine body and then transmits detected information to the driving control panel, so that the posture of the screed of the paver can be calibrated.

Both sides of mount table 1 all are provided with fixed hook plate 3 and joint subassembly, can fix the both sides of cross slope sensor 2, when dismantling cross slope sensor 2, peg graft the hand in slot 9, afterwards with swash plate 10 contact, pull swash plate 10 by force, make it drive arm-tie 6 rotate around the connecting axle, make arm-tie 6 break away from with the inside wall of recess 8, drive bellying 7 and the inside wall of recess 8 simultaneously and break away from, thereby contact fixedly to fixed hook plate 3, afterwards with fixed hook plate 3 along the inside wall upward movement of spout 4, spout 4 is to fixed hook plate 3 direction, make fixed hook plate 3 break away from with the surface of cross slope sensor 2, drive the inside wall of locating piece 14 and constant head tank 15 simultaneously, thereby contact spacing to cross slope sensor 2, afterwards take off cross slope sensor 2 from the surface of mount table 1, accomplish the dismantlement to cross slope sensor 2.

When the transverse slope sensor 2 is installed, the transverse slope sensor 2 is firstly placed at the top of the installation table 1, so that convex plates at two sides of the transverse slope sensor 2 are positioned in the fixing hook plate 3, then the fixing hook plate 3 is pulled downwards, the fixing hook plate 3 drives the guide rod 5 to move along the inner side wall of the limit groove, the limit groove and the guide rod 5 can guide and limit the fixing hook plate 3, meanwhile, the fixing hook plate 3 drives the pull plate 6 to move, the fixing hook plate 3 drives the positioning block 14 to be inserted into the positioning groove 15, the transverse slope sensor 2 is moved during insertion, the positioning groove 15 is opposite to the positioning block 14, then the positioning block 14 can be inserted into the positioning groove 15 along the inclined surface of the guide groove 16, the guide groove 16 can guide the positioning block 14, the positioning block 14 can be conveniently inserted into the positioning groove 15, the fixing hook plate 3 moves to be contacted with the surface of the transverse slope sensor 2, the pull plate 6 rotates around the connecting shaft, so that the pull plate 6 enters the groove 8, the protruding portion 7 is driven to enter the groove 8 along the arc groove, the protruding portion 7 can extrude the inner side wall of the groove 8, the protruding portion 7 is tightly attached to the inner side wall of the groove 8, the pull plate 6 is clamped in the groove 8, the fixing hook plate 3 can be pulled to be tightly attached to the surface of the transverse slope sensor 2, the transverse slope sensor 2 can be clamped and limited, the transverse slope sensor 2 is installed, the clamping plate 12 is rotated around the fixing rod 11, the clamping plate 12 is placed on the surface of the placing plate 13, the clamping plate 12 is contacted with the surface of the pull plate 6, the clamping plate 12 can limit the pull plate 6 in the groove 8, the pull plate 6 is prevented from being separated from the groove 8, and the stability of fixing the transverse slope sensor 2 is improved.

Through setting up fixed board 3 and joint subassembly that colludes, reached can install fixedly to the horizontal slope sensor 2 through the centre gripping formula, need not use assembly and disassembly tools to twist the bolt and fix to improve the advantage of installation effectiveness, solved and need carry out the dismouting through assembly and disassembly tools, caused the dismouting process more troublesome, dismantle the more problem of the time that expends.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (7)

1. Screed gesture monitoring structure of paver, its characterized in that includes:

the mounting table is mounted on the screed plate, and the top surface of the mounting table is detachably provided with a transverse slope sensor which is used for monitoring the inclination state and the gradient value of the screed plate;

the fixed hook plate is arranged on the mounting table, is assembled to be arranged on the side surface of the mounting table in a vertical sliding mode, and is fixed through the clamping assembly on the fixed hook plate so that the fixed hook plate can be hooked on the surface of the transverse slope sensor.

2. The screed attitude monitoring structure of a paving machine according to claim 1, wherein: the side of mount table has been seted up the spout, fixed hook plate slides and sets up the inside wall at the spout, fixed hook plate sets up to L shape, the side integrated into one piece of fixed hook plate has the guide bar, the spacing groove that can with guide bar movable looks adaptation has all been seted up to the inside both sides of spout.

3. The screed attitude monitoring structure of a paving machine according to claim 1, wherein: the clamping assembly comprises a pull plate and a protruding portion, wherein the side face of the mounting table is provided with a groove, the groove is communicated with the sliding groove, the pull plate is movably connected to the inner side wall of the groove, the pull plate is arranged to be convex, the top of the pull plate is connected with one end of the fixed hook plate through a connecting shaft, the protruding portion is integrally formed on one side of the pull plate, the protruding portion is tightly attached to the inner side top of the groove, the protruding portion is arranged to be arc-shaped, and an arc-shaped groove is formed in the inner side wall of the groove.

4. A screed position monitoring structure of a paving machine according to claim 3, wherein: the slot is formed in one side, far away from the fixed hook plate, of the pulling plate, an outwards inclined plate is fixedly arranged on the inner side wall of the slot, and the inclined plate is used for pulling the pulling plate to move after being held by a hand.

5. A screed position monitoring structure of a paving machine according to claim 3, wherein: the side of mount table is provided with the cardboard through the dead lever, the dead lever is fixed to be set up at the surface of mount table, the dead lever sets up to the T shape, the cardboard is closely cup jointed at the surface of dead lever, the fixed surface of arm-tie is provided with takes the board, it sets up to L shape to take the board, the cardboard is taken and is put the surface of board, cardboard and the surface swing joint of arm-tie.

6. The screed attitude monitoring structure of a paving machine according to claim 1, wherein: the surface of the fixed hook plate is fixedly provided with a positioning block, the surface of the transverse slope sensor is provided with a positioning groove which can be matched with the positioning block, and the positioning block is movably inserted into the inner side wall of the positioning groove.

7. The screed attitude monitoring structure of a paving machine according to claim 6, wherein: the opening part of the positioning groove is provided with a guide groove, the guide groove is obliquely arranged, and the guide groove is used for guiding the positioning block during insertion.