JP7164969B2 - Ready-mixed concrete quantity estimating device and mixer truck equipped with the same - Google Patents

Description

The present invention relates to a device for estimating the amount of ready-mixed concrete in a mixer drum and a mixer truck provided with the device.

Patent Literature 1 discloses a ready-mixed concrete amount estimating device for estimating the amount of ready-mixed concrete in a mixer drum in a mixer truck having a mixer drum capable of loading so-called ready-mixed concrete such as mortar and ready-mixed concrete as contents. In this ready-mixed concrete amount estimating apparatus, the ready-mixed concrete amount is estimated based on the area occupied by the ready-mixed concrete in the captured image of the inside of the mixer drum.

JP 2016-68530 A

However, the apparatus for estimating the amount of ready-mixed concrete disclosed in Patent Document 1 captures an image in a state in which the ready-mixed concrete remains at the bottom of the mixer drum. For this reason, for example, when discharging fresh concrete from the mixer drum is in progress, it is necessary to suspend the discharging operation once in order to estimate the amount of fresh concrete. If the operation of the mixer drum is interrupted each time the amount of ready-mixed concrete is estimated in this way, there is a risk that the work efficiency of the placing work or the like will be reduced.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a ready-mixed concrete amount estimating apparatus capable of estimating the amount of ready-mixed concrete in a mixer drum even when the mixer drum is being operated. do.

In a first invention, a ready-mixed concrete amount estimating device for estimating the amount of ready-mixed concrete in a mixer drum includes a sinking detection unit for detecting the amount of sinking of a base supporting the mixer drum toward the ground, and a sinking detection unit. a controller for estimating the amount of ready-mixed concrete in the mixer drum based on the detected amount of sinking of the pedestal, the controller estimating the amount of ready-mixed concrete detected by the sinking detection unit when no fresh concrete is loaded in the mixer drum. The amount of sinking before loading, the amount of sinking after loading detected by the sinking detector in the state where ready-mixed concrete is loaded in the mixer drum, and the amount of sinking after loading is detected after the amount of sinking before loading is detected. a storage unit for storing the amount of ready-mixed concrete put into the mixer drum every time the ready-mixed concrete is put into the mixer drum, and a storage unit each time the ready-mixed concrete is put into the mixer drum Based on the amount of sinking before loading, the amount of sinking after loading, and the amount of input stored in , the correlation between the amount of sinking of the frame and the amount of freshly mixed concrete in the mixer drum is calculated. Based on the correlation calculated by the calculation unit each time ready-mixed concrete is thrown into the mixer drum, the current subsidence amount detected by the subsidence detection unit is used to determine the current and an estimating unit for estimating the amount of ready-mixed concrete.

In the first invention, the controller calculates the correlation between the subsidence amount of the base and the amount of ready-mixed concrete in the mixer drum based on the pre-loading subsidence amount, post-loading subsidence amount, and input amount, Based on the calculated correlation, the current amount of ready-mixed concrete in the mixer drum is estimated from the current sinking amount detected by the sinking detector. Therefore, even during the discharging operation of discharging the fresh concrete from the mixer drum, the operator can grasp the remaining amount of the fresh concrete in the mixer drum without interrupting the operation.

According to a second aspect of the present invention, the storage unit pre-stores a change tendency of the subsidence amount of the cradle portion that changes according to the amount of ready-mixed concrete loaded in the mixer drum, and the estimation unit stores the estimated amount of sinking in the mixer drum is characterized by correcting the current amount of ready-mixed concrete based on this change trend.

In the second invention, the current amount of ready-mixed concrete in the mixer drum estimated by the estimating section is corrected based on the trend of change in the subsidence amount of the pedestal that changes according to the amount of ready-mixed concrete loaded in the mixer drum. be. In this manner, the estimation accuracy can be improved by correcting the estimated amount based on the trend of change in the sinking amount of the gantry, which differs from vehicle to vehicle due to the characteristics of the shock absorber or the like.

In a third invention, the ready-mixed concrete amount estimating apparatus further includes a tilt detection unit that detects the tilt of the mixer vehicle, the controller corrects the correlation based on the tilt of the mixer vehicle detected by the tilt detection unit, It is characterized by estimating the current amount of ready-mixed concrete in the mixer drum based on the corrected correlation.

According to a fourth aspect of the present invention, the storage unit stores the tilt amount before loading detected by the tilt detecting unit when the amount of sinking before loading is stored, and the tilt detecting unit detects the amount of sinking after loading when the amount of sinking after loading is stored. The detected post-loading tilt amount is further stored, and the computing unit corrects the pre-loading sinking amount by the pre-loading tilt amount, and corrects the post-loading sinking amount by the post-loading tilt amount to determine the correlation. Based on the corrected correlation, the estimating unit calculates the actual current amount obtained by correcting the current subsidence amount detected by the subsidence detecting unit by the current tilt amount detected by the tilt detecting unit. It is characterized by estimating the current amount of ready-mixed concrete in the mixer drum from the amount of sinking.

In the third and fourth inventions, the correlation is corrected based on the tilt of the mixer wheel detected by the tilt detector, and the current amount of ready-mixed concrete in the mixer drum is estimated based on the corrected correlation. Therefore, even if the tilt of the pedestal is different when the ready-mixed concrete is loaded and when the ready-mixed concrete is discharged, the amount of the ready-mixed concrete in the mixer drum can be accurately estimated.

A fifth aspect of the present invention is characterized in that the ready-mixed concrete amount estimating device further comprises a display section for displaying the current ready-mixed concrete amount in the mixer drum estimated by the controller.

In the fifth invention, the current amount of ready-mixed concrete in the mixer drum estimated by the controller is displayed on the display. By viewing the current amount of ready-mixed concrete in the mixer drum displayed on the display unit, the operator can grasp the remaining amount of ready-mixed concrete in the mixer drum without interrupting the discharge operation. can.

A sixth aspect of the invention is characterized in that the ready-mixed concrete amount estimating device further comprises a transmitter capable of transmitting the current ready-mixed concrete amount in the mixer drum estimated by the controller to the outside.

In the sixth invention, the current amount of ready-mixed concrete in the mixer drum estimated by the controller is transmitted to the outside by the transmitter. Therefore, the concrete plant can grasp the current amounts of ready-mixed concrete in the mixer drums of the plurality of mixer trucks, and can efficiently deliver the ready-mixed concrete to the work site without excess or deficiency.

According to a seventh aspect of the present invention, the subsidence detection unit is provided at least at a position capable of detecting the subsidence amount of the pedestal on the side where the ready-mixed concrete is biased in the mixer drum when the ready-mixed concrete in the mixer drum is discharged. Characterized by

In the seventh aspect of the invention, the subsidence detector is provided at a position where the subsidence amount of the base part on the side where the ready-mixed concrete is biased can be detected in the mixer drum. In this way, by providing the sinking detector in a portion where the change in the sinking amount of the gantry is relatively large, it is possible to improve the estimation accuracy.

An eighth aspect of the invention is characterized in that a plurality of sinking detectors are arranged at predetermined intervals in at least one of the longitudinal direction and the width direction of the mixer vehicle.

In the eighth invention, a plurality of sinking detectors are arranged at predetermined intervals in at least one of the longitudinal direction and the width direction of the mixer vehicle. By estimating the amount of ready-mixed concrete in the mixer drum based on the output values of the plurality of sinking detectors arranged in this manner, the estimation accuracy can be improved.

A ninth invention is characterized in that a mixer truck is equipped with the ready-mixed concrete amount estimating device of any one of the first to eighth inventions.

In a ninth invention, a mixer truck is provided with the ready-mixed concrete amount estimating device of the first to eighth inventions. Therefore, regardless of the operating state of the mixer drum, the amount of ready-mixed concrete in the mixer drum of the mixer truck can be easily grasped.

According to the present invention, the amount of ready-mixed concrete in the mixer drum can be estimated regardless of the operating state of the mixer drum.

BRIEF DESCRIPTION OF THE DRAWINGS It is a side view of the mixer truck which mounts the ready-mixed concrete amount estimation apparatus which concerns on embodiment of this invention. 1 is a block diagram showing an apparatus for estimating the amount of ready-mixed concrete according to an embodiment of the present invention; FIG. 4 is a flow chart when estimating the amount of ready-mixed concrete in the apparatus for estimating the amount of ready-mixed concrete according to the embodiment of the present invention. It is a graph which shows the correlation between the amount of sinking and the amount of ready-mixed concrete. It is a graph which shows the change tendency of the subduction amount which changes according to the amount of ready-mixed concrete. 7 is a graph showing correction coefficients according to the amount of sinking; FIG. 5 is a diagram for explaining the difference between an actual amount of subduction and a detected amount of subduction when tilted; 5 is a flow chart when estimating the amount of ready-mixed concrete in consideration of the amount of inclination in the apparatus for estimating the amount of ready-mixed concrete according to the embodiment of the present invention. FIG. 5 is a diagram for explaining calculation of an actual sinking amount before loading; FIG. 10 is a diagram for explaining calculation of an actual sinking amount after loading; 4 is a graph showing the correlation between the amount of subsidence corrected based on the inclination and the amount of ready-mixed concrete.

Hereinafter, a ready-mixed concrete amount estimation device according to an embodiment of the present invention will be described with reference to the drawings.

First, referring to FIG. 1, the overall configuration of a mixer truck 10 having a ready-mixed concrete amount estimating device 100 will be described.

The mixer truck 10 is a vehicle for transporting so-called ready-mixed concrete such as mortar and ready-mixed concrete (hereinafter referred to as “ready-mixed concrete”) charged into the mixer drum 2 . In the following description, a case where the mixer truck 10 loads ready-mixed concrete as a load will be described.

As shown in FIG. 1, the mixer truck 10 includes a base portion 1 arranged on a chassis frame 11 and extending in the longitudinal direction of the vehicle, a mixer drum 2 rotatably mounted on the base portion 1, and the mixer drum 2 being driven to rotate. a hopper 4 for guiding freshly mixed concrete fed from the outside into the mixer drum 2; and a chute 5 for guiding the freshly mixed concrete discharged from the mixer drum 2 to a predetermined position.

The mixer drum 2 is a cylindrical container that rotates about a rotation axis C1. is provided with a drive shaft 2b extending outward along the rotation axis C1. The mixer drum 2 is supported by the pedestal 1 in a state in which the rear end side provided with the opening 2a is lifted higher than the front end side.

A drive shaft 2b of the mixer drum 2 is connected to a hydraulic motor (not shown) provided in the drum drive device 7 via a gearbox (not shown). Therefore, the mixer drum 2 is rotationally driven in the forward rotation direction or the reverse rotation direction by the hydraulic motor. The drive shaft 2b of the mixer drum 2 may be connected to a running engine (not shown) of the mixer truck 10 via a gearbox. In this case, the mixer drum 2 is rotationally driven by the running engine. Also, as the motor for rotating the mixer drum 2, an electric motor may be used instead of the hydraulic motor.

Inside the mixer drum 2, a pair of blades 3a and 3b are spirally arranged along the inner wall surface of the mixer drum 2. As shown in FIG. By rotating the pair of blades 3a and 3b together with the mixer drum 2, the ready-mixed concrete put into the mixer drum 2 is stirred.

The hopper 4 is arranged above the opening 2 a of the mixer drum 2 to guide the ready-mixed concrete charged from above the mixer truck 10 into the mixer drum 2 . On the other hand, below the opening 2a of the mixer drum 2, a chute 5 is arranged to guide the ready-mixed concrete discharged from the mixer drum 2 to a predetermined position.

In the mixer truck 10 configured as described above, when the mixer drum 2 is rotationally driven in the forward rotation direction, which is the counterclockwise rotation as viewed from the rear of the vehicle, the blades 3a and 3b move forward of the mixer drum 2 while stirring the ready-mixed concrete in the mixer drum 2. and move. On the other hand, when the mixer drum 2 is rotationally driven in the reverse rotation direction, the blades 3a and 3b are moved to the rear of the mixer drum 2 while stirring the ready-mixed concrete. By rotating the mixer drum 2 in the reverse direction in this manner, the ready-mixed concrete can be discharged from the opening 2 a of the mixer drum 2 . The ready-mixed concrete discharged from the opening 2 a of the mixer drum 2 is guided to a predetermined position via the chute 5 .

When the raw concrete is charged into the mixer drum 2 through the hopper 4, the mixer drum 2 is rotated forward at a higher speed than during stirring to quickly move the charged raw concrete to the front of the mixer drum 2.例文帳に追加Note that the blades 3a and 3b may be arranged so that the rotation in the right direction as viewed from the rear of the vehicle is the forward rotation direction.

Next, the ready-mixed concrete quantity estimation device 100 for estimating the quantity of ready-mixed concrete in the mixer drum 2 will be described.

As shown in FIG. 2, ready-mixed concrete amount estimating apparatus 100 includes distance sensor 20 as a sinking detection unit for detecting the amount of sinking of base unit 1 that supports mixer drum 2 toward the ground, and inclination of mixer truck 10. a controller 30 for estimating the amount of ready-mixed concrete in the mixer drum 2 based on the detected values of the distance sensor 20 and the tilt sensor 22; An input unit 40, a display unit 50 for displaying the amount of fresh concrete estimated by the controller 30, and a transmission unit 60 capable of transmitting the amount of ready-mixed concrete estimated by the controller 30 to the outside are provided.

As shown in FIG. 1, the distance sensor 20 is a laser displacement sensor that is provided on the pedestal 1 and measures the distance between the pedestal 1 and the axle of the rear wheel (not shown). Here, the distance between the pedestal 1 and the axle assembled to the chassis frame 11 via a shock absorber (not shown) changes as the shock absorber expands and contracts according to the weight on the cradle 1 . That is, by detecting a change in the distance between the gantry 1 and the axle with the distance sensor 20, the subsidence amount of the gantry 1 toward the ground is detected. The sinking amount of the gantry 1 detected by the distance sensor 20 is input to the controller 30 by wired or wireless communication means.

Note that the distance sensor 20 is not limited to measuring a change in the distance between the gantry 1 and the axle. It may also be provided on the chassis frame 11 to measure changes in the distance between the chassis frame 11 and the axle or the distance between the chassis frame 11 and the ground. In general, since the ground surface is uneven and error is likely to occur in the detected value, the distance sensor 20 measures the change in the distance between the so-called sprung member and unsprung member that are connected via the shock absorber. It is preferable that

Further, the distance sensor 20 is not limited to a displacement sensor using a laser, and may be of any type as long as it can detect the amount of sinking of the gantry 1 toward the ground. Sound waves may be used. In addition, when the amount of subduction of the pedestal 1 toward the ground changes, the shock absorber also deforms. Therefore, for example, a stroke sensor that detects the amount of expansion and contraction of the damper that constitutes the shock absorber can be used as the subduction detector. is. Further, when the amount of sinking of the gantry part 1 toward the ground changes, the amount of strain generated in the gantry part 1 and the chassis frame 11 also changes. can also be used as a subduction detector.

As shown in FIG. 1, the tilt sensor 22 is provided on the gantry 1 in the same manner as the distance sensor 20, and is a sensor that detects the amount of tilt of the mixer truck 10 with respect to the horizontal plane in the longitudinal direction and the width direction of the vehicle. The tilt amount of the mixer truck 10 detected by the tilt sensor 22 is input to the controller 30 by wired or wireless communication means. The tilt sensor 22 may be provided anywhere as long as the tilt of the mixer truck 10 can be detected, and may be provided on the chassis frame 11 .

The controller 30 is composed of a microcomputer having a CPU (central processing unit), ROM (read only memory), RAM (random access memory), and I/O interface (input/output interface). It is installed in a place where there is little possibility of ingress of dirt and dust. The RAM stores data in CPU processing, the ROM stores CPU control programs and the like in advance, and the I/O interface is used for inputting and outputting information with connected devices. The controller 30 may be composed of a plurality of microcomputers.

The controller 30, as shown in FIG. A current ready-mixed concrete in the mixer drum 2 is calculated using the calculation unit 32 that performs a predetermined calculation using the distance sensor 20 and the tilt sensor 22, the values stored in the storage unit 31, and the calculated values calculated by the calculation unit 32. and an estimation unit 33 for estimating the quantity. The function of each part will be described in detail in the explanation of the method for estimating the amount of fresh concrete, which will be described later. Note that the storage unit 31, the calculation unit 32, and the estimation unit 33 represent the functions of the controller 30 as virtual units, and do not mean that they physically exist. For example, the computation and estimation performed by the computing unit 32 and the estimating unit 33 are mainly performed by the CPU, and the storage performed by the storage unit 31 is performed by RAM and ROM.

The input unit 40 is an operation panel for an operator to input the amount of ready-mixed concrete to be input, and is provided near an operation unit (not shown) for operating the rotation of the mixer drum 2 or in the driver's seat. Information such as the amount of raw concrete input via the input unit 40 is transmitted to the controller 30 by wired or wireless communication means. Note that the input unit 40 may be a mobile terminal that can be carried by the worker.

The display unit 50 is a monitor that displays the amount of ready-mixed concrete estimated by the estimation unit 33 in numerical values and graphs, and is provided integrally with the input unit 40 . The amount of ready-mixed concrete estimated by the estimating unit 33 is transmitted to the display unit 50 by wired or wireless communication means, and the operator can determine the current amount of ready-mixed concrete in the mixer drum 2 by viewing the content displayed on the display unit 50. can grasp. Note that the display unit 50 may be provided separately from the input unit 40 .

The transmission unit 60 is a wireless communication unit compatible with a wireless LAN such as Wi-Fi (registered trademark) or a wireless communication unit compatible with a mobile phone communication network such as third generation mobile communication (3G). provided in The amount of ready-mixed concrete estimated by the estimation unit 33 is transmitted to an external facility such as a concrete plant via the transmission unit 60 . In addition, the transmission unit 60 may be arranged at a place exposed to the outside in order to maintain a good state of communication with the outside.

Next, a method for estimating the current amount of ready-mixed concrete in the mixer drum 2 by the ready-mixed concrete amount estimation apparatus 100 will be described with reference to the flowchart of FIG. 3 and the graph of FIG.

First, in step S11, it is detected whether or not the mixer drum 2 is loaded with ready-mixed concrete. Specifically, when the mixer truck 10 stops at a concrete plant and is waiting for ready-mixed concrete to be added, the operator inputs through the input unit 40 that the mixer drum 2 is in the "pre-loading state." Then, the controller 30 determines that the mixer drum 2 is not loaded with ready-mixed concrete. Whether or not ready-mixed concrete is loaded in the mixer drum 2 is determined by positional information indicating that the mixer truck 10 is located in a concrete plant and driving state information indicating that the driving load of the mixer drum 2 is low. It may be determined from information.

When the state of the mixer drum 2 is determined to be the "pre-loading state", the process proceeds to step S12, and the sinking amount detected by the distance sensor 20 when the "pre-loading state" is determined in the storage unit 31. is stored as the sinking amount S1 before loading.

Subsequently, in step S13, it is determined whether or not the input amount V1 of the ready-mixed concrete has been input via the input unit 40 or not. The input amount V1 of the ready-mixed concrete that is input into the mixer drum 2 after the operator inputs that it is in the "pre-loading state" is usually measured in a concrete plant. When the input amount V1 thus measured is input to the input unit 40 by the worker, the process proceeds to step S14, and the input amount V1 of the ready-mixed concrete input by the operator is stored in the storage unit 31. The sinking amount detected by the distance sensor 20 when the amount V1 is input is stored as the post-loading sinking amount S2. The input of the input amount V1 may be performed by the mixer truck 10 receiving the input amount V1 transmitted from the concrete plant by wireless communication instead of being input manually by the worker.

In this way, the storage unit 31 stores the pre-loading sinking amount S1 detected by the distance sensor 20 when no fresh concrete is loaded in the mixer drum 2, and the distance sensor 20, and an input amount V1 of ready-mixed concrete input into the mixer drum 2 during the period from the detection of the pre-loading sinking amount S1 to the detection of the post-loading sinking amount S2. and are stored. The amount of sinking before loading S1, the amount of sinking after loading S2, and the amount of input V1 are updated every time the ready-mixed concrete is input into the mixer drum 2 in the concrete plant.

When the pre-loading sinking amount S1, the post-loading sinking amount S2, and the input amount V1 are stored in the storage unit 31, the calculating unit 32 calculates the sinking amount of the gantry unit 1 based on these values in the following step S15. A correlation with the amount of fresh concrete is calculated. Specifically, as shown in FIG. 4, the amount of ready-mixed concrete when the amount of sinking is the amount of sinking before loading S1 is set to zero, and the amount of ready-mixed concrete when the amount of sinking is the amount of sinking after loading S2 is added. A straight line (linear function) drawn when the quantity is V1 is expressed as a formula. The correlation between the amount of subsidence of the gantry 1 and the amount of fresh concrete, which is mathematically expressed in this way, is stored in the storage unit 31 .

Next, in step S16, the amount of ready-mixed concrete in the mixer drum 2 is estimated based on the correlation between the sinking amount of the gantry 1 and the amount of ready-made concrete calculated in step S15. Specifically, when the current sinking amount Sn detected by the distance sensor 20 is input to the estimating unit 33, the estimating unit 33 performs an estimation corresponding to the current sinking amount Sn, as shown in FIG. The amount Vn is calculated using the linear function stored in the storage unit 31, and the calculated value is output as the current amount of fresh concrete in the mixer drum 2 (estimated amount Vn).

Specifically, for example, when the sinking amount S1 before loading is 50 mm, the sinking amount S2 after loading is 150 mm, and the input amount V1 is 5.0 m ³ ,
Estimated amount Vn = 0.05 * current sinking amount Sn - 2.5
A formula of a linear function is obtained. If the current sinking amount Sn is 120 mm, the current amount of ready-mixed concrete in the mixer drum 2 is estimated to be 3.5 m ³ from this formula.

It should be noted that the current amount of ready-mixed concrete in the mixer drum 2 may be estimated by the following process instead of using the linear function formula described above.

When the pre-loading sinking amount S1 is 50 mm, the post-loading sinking amount S2 is 150 mm, and the input amount V1 is 5.0 m ³ , the mount 1 is 100 mm for the ready-mixed concrete amount of 5.0 m ³ . It will only sink. In this case, it is estimated that the amount of ready-mixed concrete in the mixer drum 2 will change by 0.05 m ³ if the sinking amount of the base 1 changes by 1 mm. Therefore, if the current amount of sinking Sn is 120 mm, the amount of sinking is reduced by ³⁰ mm compared to the amount of sinking S2 after loading. It is estimated that 3.5 m ³ of ready-mixed concrete remains in the mixer drum 2 .

When the estimation of the amount of ready-mixed concrete is completed in step S16 in this way, the estimated amount Vn estimated by the estimation unit 33 is displayed on the display unit 50 in subsequent step S17. The display unit 50 displays specific numerical values and graphs such as "remaining 3.5 m ³ " and "remaining 70%", for example. Therefore, the operator can easily grasp the current amount of ready-mixed concrete in the mixer drum 2, that is, the remaining amount of ready-mixed concrete, by looking at the content displayed on the display unit 50 .

In the subsequent step S18, it is determined whether or not the operator has issued an instruction to end the estimation of the amount of ready-mixed concrete via the input unit 40. FIG. When the operator presses an estimation end button displayed on the input unit 40, the controller 30 ends the estimation of the amount of ready-mixed concrete. On the other hand, the controller 30 continues estimating the amount of ready-mixed concrete unless the estimation end button is pressed by the operator.

That is, if the estimation end button is not pressed, the controller 30 sequentially acquires the current sinking amount Sn detected by the distance sensor 20, and sequentially outputs the estimated amount Vn corresponding to the captured current sinking amount Sn. do. Therefore, the display unit 50 displays in real time the current amount of ready-mixed concrete in the mixer drum 2 that gradually decreases due to the operation of discharging the ready-mixed concrete from the mixer drum 2 . The time interval at which the controller 30 acquires the current sinking amount Sn detected by the distance sensor 20 can be set to an appropriate length by the operator.

In this way, since the current amount of ready-mixed concrete in the mixer drum 2 is displayed on the display unit 50, the worker can control the contents of the mixer drum 2 simply by looking at the display unit 50 without interrupting the discharging operation even during the discharging operation. It is possible to grasp the remaining amount of ready-mixed concrete in real time. In addition, even an inexperienced worker can easily grasp the remaining amount of ready-mixed concrete, and the remaining amount of ready-mixed concrete can be easily reported by showing the display unit 50 to the field supervisor at the casting site. It becomes possible to In addition, it is possible to prevent variations in grasping of the remaining amount of ready-mixed concrete in the mixer drum 2 due to differences in operator experience.

The estimated amount Vn estimated by the estimation unit 33 can also be transmitted to the concrete plant via the transmission unit 60 in real time. For this reason, for example, the current amount of ready-mixed concrete in the mixer drums 2 of the plurality of mixer trucks 10 can be grasped in real time at the concrete plant, and the ready-mixed concrete can be efficiently delivered to the work site without excess or deficiency. Moreover, as a result, the amount of ready-mixed concrete discarded is reduced, and the delivery efficiency of the mixer truck 10 is improved, so that the production cost and delivery cost of the ready-mixed concrete can be reduced.

When the discharge work at the work site is completed, the mixer truck 10 returns to the concrete plant again. Then, when ready-mixed concrete can be put in, the operator inputs through the input unit 40 that the state of the mixer drum 2 is the "pre-loading state", and the pre-loading sinking amount S1, A post-loading sinking amount S2 and an input amount V1 are stored.

In this way, these values stored in the storage unit 31 are updated each time ready-mixed concrete is put into the mixer drum 2 in the concrete plant, so the elastic modulus of the leaf springs, etc., that constitute the shock absorber may change over time. Even if it changes, it will not affect the estimation of the amount of ready-mixed concrete. In addition, since these values stored in the storage unit 31 are different for each truck mixer 10, it is possible to accurately estimate the amount of ready-mixed concrete for each truck mixer 10. FIG.

In step S14, the timing for storing the post-loading sinking amount S2 in the storage unit 31, that is, the timing for the operator to input the input amount V1 of the ready-mixed concrete via the input unit 40, is the timing of entering the mixer drum 2 in the concrete plant. Any timing is acceptable as long as it is from the completion of feeding of the ready-mixed concrete to before the ready-mixed concrete is discharged from the mixer drum 2 at the work site.

However, in order to improve the accuracy of estimating the amount of ready-mixed concrete, the timing of storing the post-loading sinking amount S2 in the storage unit 31 should be closer to the work site than when the ready-mixed concrete has been completely charged into the mixer drum 2 in the concrete plant. It is preferable that it is immediately before the ready-mixed concrete is discharged from the mixer drum 2 at . The reason why it is preferable to store the post-loading sinking amount S2 in the storage unit 31 immediately before the ready-mixed concrete is discharged from the mixer drum 2 will be described below.

The amount of ready-mixed concrete needs to be estimated mainly during the operation of discharging the ready-mixed concrete from the mixer drum 2 . When discharging the ready-mixed concrete from the mixer drum 2, the mixer drum 2 is rotationally driven in the reverse rotation direction, which is the clockwise rotation as viewed from the rear of the vehicle. At this time, the ready-mixed concrete in the mixer drum 2 is shifted to the left side of the mixer drum 2 as viewed from the rear of the vehicle while being stirred. For this reason, the amount of sinking of the left side of the gantry part 1 becomes large when viewed from the rear of the vehicle.

On the other hand, when the ready-mixed concrete is completely charged into the mixer drum 2 in the concrete plant, the mixer drum 2 is rotationally driven in the forward rotation direction, which is counterclockwise as viewed from the rear of the vehicle. For this reason, the sinking amount of the pedestal 1 is greater on the right side of the pedestal 1 when viewed from the rear of the vehicle, which is the opposite side to the discharge of the ready-mixed concrete.

Therefore, if the distance sensor 20 is provided on the left side as viewed from the rear of the vehicle, the sinking amount output from the distance sensor 20 is greater than when the ready-mixed concrete is completely charged into the mixer drum 2 in the concrete plant. It becomes larger just before the ready-mixed concrete is discharged. Therefore, if the post-loading sinking amount S2 is stored in the storage unit 31 when the feeding of the ready-mixed concrete is completed, the estimated amount Vn of the ready-mixed concrete estimated at the time of discharging the ready-mixed concrete is overestimated. Become.

Similarly, when the distance sensor 20 is provided on the right side as viewed from the rear of the vehicle, the amount of sinking output from the distance sensor 20 is greater when the ready-mixed concrete is completely charged than immediately before the ready-mixed concrete is discharged. growing. Therefore, if the post-loading sinking amount S2 is stored in the storage unit 31 when the feeding of the ready-mixed concrete is completed, the estimated amount Vn of the ready-mixed concrete that is estimated when the ready-mixed concrete is discharged will be underestimated. Become.

In this way, if the post-loading sinking amount S2 is stored in the storage unit 31 when the feeding of the ready-mixed concrete is completed, an estimation error may occur. It is preferable that the timing to be stored is immediately before the fresh concrete is discharged from the mixer drum 2 .

Further, as described above, when the ready-mixed concrete is discharged, the amount of sinking of the left side of the gantry 1 as viewed from the rear of the vehicle becomes large. That is, the left side of the pedestal 1 as viewed from the rear of the vehicle has a greater rate of change in the sinking amount with respect to the predetermined amount of discharged ready-mixed concrete while discharging the ready-mixed concrete from the mixer drum 2 than the right side thereof. . Since the accuracy of estimating the amount of ready-mixed concrete in the mixer drum 2 can be improved by providing the distance sensor 20 in a portion where the change in the amount of sinking is relatively large, the distance sensor 20 is positioned on the left side as viewed from the rear of the vehicle. It is preferable to provide them close to each other. When the mixer truck 10 is designed to discharge the ready-mixed concrete from the mixer drum 2 by driving the mixer drum 2 to rotate counterclockwise as viewed from the rear of the vehicle, when discharging the ready-mixed concrete, the pedestal portion as viewed from the rear of the vehicle Since the amount of sinking on the right side of 1 becomes large, it is preferable to provide the distance sensor 20 on the right side as viewed from the rear of the vehicle.

In order to improve the estimation accuracy, it is preferable to provide a plurality of distance sensors 20 and output the average value of the estimated amounts Vn estimated based on the output values of the respective distance sensors 20 as the final estimated amount Vn. . As described above, when the ready-mixed concrete is charged into the mixer drum 2 and when the ready-mixed concrete is discharged from the mixer drum 2, the direction of rotation of the mixer drum 2 is switched, so that the position at which the ready-mixed concrete is biased in the mixer drum 2 is shifted in the longitudinal direction of the vehicle and the position in which the ready-mixed concrete is biased. It will change in the left and right direction. When the position where the ready-mixed concrete is biased in the mixer drum 2 changes in this way, a difference occurs in the amount of sinking of the gantry 1 on the left and right sides as viewed from the rear of the vehicle, and the amount of sinking of the gantry 1 also differs in the front-to-rear direction of the vehicle. will occur. Therefore, when a plurality of distance sensors 20 are provided, it is preferable to arrange the distance sensors 20 symmetrically in the width direction of the vehicle, or arrange the distance sensors 20 at predetermined intervals in the longitudinal direction of the vehicle. .

Next, two correction methods for improving the accuracy of estimating the amount of fresh concrete in the mixer drum 2 will be described.

First, the first correction method will be described with reference to FIGS. 5A and 5B.

In the above-described method for estimating the amount of ready-mixed concrete, the amount of ready-mixed concrete is estimated on the assumption that the amount of subsidence of the gantry 1 and the amount of ready-made concrete are proportional. However, the correlation between the amount of sinking of the gantry 1 and the amount of ready-mixed concrete changes depending on the characteristics of the shock absorber, and there are cases where the relationship is curved, for example, as indicated by the solid line in FIG. 5A.

For this reason, the storage unit 31 stores in advance the change tendency of the sinking amount of the pedestal unit 1 that changes according to the amount of ready-mixed concrete loaded in the mixer drum 2 . Specifically, for example, 0.5 m ³ of ready-mixed concrete is put into the mixer drum 2 in which no ready-mixed concrete is loaded. By storing the amount of subduction detected in , in the storage unit 31, a change tendency as indicated by the solid line in FIG. 5A is obtained.

Then, in the calculation unit 32, it was assumed that the correlation between the amount of subsidence and the amount of ready-mixed concrete as shown in FIG. A ratio of change tendency to case is calculated as a correction factor. Specifically, when the input amount V1 of the ready-mixed concrete input into the mixer drum 2 is the first input amount Vn1, from the pre-loading sinking amount S1 to the first sinking amount Sn1 corresponding to the first input amount Vn1 is the first correction coefficient C1 as shown in FIG. 5B. Further, when the input amount V1 of the ready-mixed concrete input into the mixer drum 2 is the second input amount Vn2 which is smaller than the first input amount Vn1, a second input amount Vn2 corresponding to the second input amount Vn2 is obtained from the sinking amount S1 before loading. The correction coefficient up to the sinking amount Sn2 is a second correction coefficient C2 larger than the first correction coefficient C1 as shown in FIG. 5B. As described above, the correction coefficient has a different magnitude depending on the amount V1 of the ready-mixed concrete charged into the mixer drum 2 .

By outputting the corrected estimator Vn obtained by multiplying the estimator 33 by the correction coefficient derived in this manner to the estimator 33 as the final estimator Vn, the estimation accuracy of the estimator Vn is increased. can be improved. In addition, since the characteristics of the shock absorber may change over time, the accuracy of estimating the amount of ready-mixed concrete in the mixer drum 2 can be further improved by periodically updating the above-described change tendency. In addition, since the above-described change tendency is obtained for each mixer truck 10, the accuracy of estimating the amount of fresh concrete in the mixer drum 2 estimated in each mixer truck 10 can be improved.

Next, the second correction method will be explained.

In general, in a concrete plant, the mixer truck 10 is charged with ready-mixed concrete in a flat place with a relatively small slope, while the work site where the ready-mixed concrete is discharged is not only a flat place but also a mountainous area with a relatively large slope. It may become a department.

As described above, the distance sensor 20 measures the change in the distance between the sprung member and the unsprung member or the ground. It is the sinking amount of the gantry part 1 in the vertical direction. However, the gantry 1 actually sinks in the direction of gravity. Therefore, as shown in FIG. 6, when the ready-mixed concrete is discharged from the mixer drum 2, if the gantry 1 is tilted with respect to the horizontal direction by an inclination amount αn, the greater the inclination amount αn, the more the distance sensor 20 The detected sinking amount Sn becomes a value smaller than the actual sinking amount Srn.

For this reason, for example, after the post-loading sinking amount S2 described above is stored in the storage unit 31 in a concrete plant or the like where the pedestal 1 has a relatively small inclination, the mixer drum is stored at a work site where the pedestal 1 has a relatively large inclination. 2, the sinking amount Sn detected by the distance sensor 20 becomes smaller than the actual sinking amount Srn, as shown in FIG. There is a risk that the amount of ready-mixed concrete may be estimated to be decreasing even though no

In order to remove such an estimation error, the controller 30 corrects the correlation between the sinking amount of the gantry 1 and the amount of fresh concrete based on the detected value of the tilt sensor 22, and based on the corrected correlation, the mixer drum Estimate the current amount of ready-mixed concrete in 2.

A method of estimating the current amount of ready-mixed concrete using this second correction method will be described with reference to FIGS. FIG. 7 is a flowchart for estimating the amount of ready-mixed concrete in consideration of the amount of inclination αn of the gantry 1, and FIGS. 9 is a graph showing the correlation between the amount of sinking and the amount of ready-mixed concrete obtained in consideration of the inclination of the gantry 1. FIG.

First, at step S21 in FIG. 7, it is detected whether or not ready-mixed concrete is not loaded in the mixer drum 2, similarly to step S11.

If the state of the mixer drum 2 is determined to be the "pre-loading state", the process proceeds to step S22, and the amount of sinking detected by the distance sensor 20 when the "pre-loading state" is determined in the storage unit 31. is stored as the pre-loading sinking amount S1, and the tilt amount detected by the tilt sensor 22 is stored as the pre-loading tilt amount α1.

Subsequently, in step S23, similarly to step S13, it is determined whether or not the input amount V1 of ready-mixed concrete has been input via the input unit 40 or not. When the input amount V1 is input to the input unit 40 by the operator, the process proceeds to step S24, and the input amount V1 of the ready-mixed concrete input by the operator is stored in the storage unit 31, and the input amount V1 is input. The sinking amount detected by the distance sensor 20 is stored as the post-loading sinking amount S2, and the tilt amount detected by the tilt sensor 22 is stored as the post-loading tilt amount α2.

In this way, the storage unit 31 stores the pre-loading sinking amount S1 detected by the distance sensor 20 when no fresh concrete is loaded in the mixer drum 2, and the distance sensor 20, and an input amount V1 of ready-mixed concrete input into the mixer drum 2 during the period from the detection of the pre-loading sinking amount S1 to the detection of the post-loading sinking amount S2. In addition, the pre-loading tilt amount α1 detected by the tilt sensor 22 when the pre-loading sinking amount S1 is stored, and the tilt sensor 22 detecting when the post-loading sinking amount S2 is stored. and the post-loading tilt amount α2 are stored.

When these values are stored in the storage unit 31, in subsequent step S25, the calculation unit 32 calculates the corrected correlation between the sinking amount of the gantry unit 1 and the amount of ready-mixed concrete based on these values. .

Specifically, first, the actual pre-loading depression amount Sr1 is calculated from the pre-loading depression amount S1 and the pre-loading inclination amount α1, and the actual loading is calculated from the post-loading depression amount S2 and the post-loading inclination amount α2. A post-sinking amount Sr2 is calculated.

Next, as shown in FIG. 9, the amount of ready-mixed concrete when the amount of sinking is the actual amount of sinking before loading Sr1 is set to zero, and the amount of ready-mixed concrete when the amount of sinking is the actual amount of sinking after loading Sr2. A straight line (linear function) drawn when is the input amount V1 is mathematically represented. The corrected correlation between the subsidence amount of the gantry 1 and the amount of fresh concrete, which is expressed as a mathematical formula in this way, is stored in the storage unit 31 .

Next, in step S26, the estimation unit 33 calculates the actual current sinking amount Srn from the current sinking amount Sn detected by the distance sensor 20 and the current tilt amount αn detected by the tilt sensor 22. calculated.

In the subsequent step S27, the mixer drum is adjusted based on the corrected correlation between the sinking amount of the gantry 1 and the amount of fresh concrete calculated in step S25 and the actual current sinking amount Srn calculated in step S26. 2 is made.

Specifically, similarly to step S16, the estimation unit 33 uses the linear function stored in the storage unit 31 to obtain the estimated amount Vn corresponding to the actual current subduction amount Srn, as shown in FIG. , and the calculated value is output as the current amount of ready-mixed concrete in the mixer drum 2 (estimated amount Vn).

When the estimation of the amount of ready-mixed concrete is completed in step S27 in this manner, the estimated amount Vn estimated by the estimation unit 33 is displayed on the display unit 50 in the following step S27, as in step S17.

Then, in the following step S29, similarly to step S18, it is determined whether or not the operator has given an instruction to finish estimating the amount of ready-mixed concrete via the input unit 40 or not. When the operator presses an estimation end button displayed on the input unit 40, the controller 30 ends the estimation of the amount of ready-mixed concrete. On the other hand, unless the estimation end button is pressed by the operator, the controller 30 continues estimating the amount of ready-mixed concrete and outputs the current amount of ready-mixed concrete in the mixer drum 2 in real time.

In this way, by estimating the current amount of ready-mixed concrete in the mixer drum 2 in consideration of the inclination of the mixer truck 10, the accuracy of estimating the amount of ready-made concrete can be improved.

In step S24, the timing of storing the post-loading sinking amount S2 and the post-loading inclination amount α2 in the storage unit 31, that is, the timing at which the worker inputs the input amount V1 of ready-mixed concrete through the input unit 40, It may be when the ready-mixed concrete is completely charged into the mixer drum 2 at the plant, or when the ready-mixed concrete is discharged from the mixer drum 2 at the work site. When the worker inputs the input amount V1 to the input unit 40 when the ready-mixed concrete has been input into the mixer drum 2 in the concrete plant, the post-loading inclination amount α2 becomes substantially the same value as the pre-loading inclination amount α1, When the worker inputs the input amount V1 to the input unit 40 when discharging the ready-mixed concrete from the mixer drum 2 at the work site, the post-loading tilt amount α2 becomes substantially the same value as the current tilt amount αn.

By correcting the estimated amount Vn by the first correction method and the second correction method in this way, the accuracy of estimating the amount of ready-mixed concrete in the mixer drum 2 can be improved. Note that both the first correction method and the second correction method may be performed at the same time. In addition, if estimation accuracy is not required, neither correction method may be performed.

According to the above embodiment, the following effects are obtained.

In the ready-mixed concrete amount estimating device 100, the controller 30 determines the amount of sinking of the gantry 1 and the amount of ready-mixed concrete in the mixer drum 2 based on the pre-loading sinking amount S1, the post-loading sinking amount S2, and the input amount V1. is calculated, and the current amount of ready-mixed concrete in the mixer drum 2 is estimated from the current sinking amount Sn detected by the distance sensor 20 based on the calculated correlation. The estimated current amount of ready-mixed concrete in the mixer drum 2 is displayed on the display unit 50 in real time.

Therefore, even during the discharging operation of discharging the ready-mixed concrete from the mixer drum 2, the worker can grasp the remaining amount of the ready-mixed concrete in the mixer drum 2 in real time by looking at the display unit 50 without interrupting the operation. . In addition, even an inexperienced worker can easily grasp the remaining amount of ready-mixed concrete, and the remaining amount of ready-mixed concrete can be easily reported by showing the display unit 50 to the field supervisor at the casting site. It becomes possible to In addition, it is possible to prevent variations in grasping of the remaining amount of ready-mixed concrete in the mixer drum 2 due to differences in operator experience.

Configurations, functions, and effects of embodiments of the present invention will be collectively described below.

The ready-mixed concrete amount estimating device 100 includes a distance sensor 20 that detects the amount of sinking of the gantry 1 that supports the mixer drum 2 toward the ground, and the mixer drum based on the amount of sinking of the gantry 1 detected by the distance sensor 20. and a controller 30 for estimating the amount of ready-mixed concrete in the mixer drum 2, the controller 30 estimating the pre-loading sinking amount S1 detected by the distance sensor 20 when no ready-mixed concrete is loaded in the mixer drum 2, and The amount of sinking after loading S2 detected by the distance sensor 20 in the state where the ready-mixed concrete is loaded, and the amount of sinking in the mixer drum 2 between the detection of the amount of sinking before loading S1 and the amount of sinking after loading S2 is detected. and a storage unit 31 that stores an input amount V1 of ready-mixed concrete that has been input to the pedestal unit 1, and based on the pre-loading sinking amount S1, the post-loading sinking amount S2, and the input amount V1, the sinking amount of the gantry 1 and the mixer drum 2 A calculation unit 32 for calculating the correlation between the amount of ready-mixed concrete in the mixer drum 2 and the current amount of ready-mixed concrete in the mixer drum 2 is estimated from the current sinking amount Sn detected by the distance sensor 20 based on the correlation. and an estimation unit 33 .

In this configuration, the controller 30 determines the correlation between the amount of sinking of the gantry 1 and the amount of ready-mixed concrete in the mixer drum 2 based on the amount of sinking S1 before loading, the amount of sinking S2 after loading, and the amount of input V1. Based on the computed correlation, the current amount of fresh concrete in the mixer drum 2 is estimated from the current sinking amount Sn detected by the distance sensor 20 . Therefore, by viewing the current amount of ready-mixed concrete in the mixer drum 2 displayed on the display unit 50, the worker can control the mixer drum 2 without interrupting the discharge operation of discharging the ready-mixed concrete from the mixer drum 2 even during the discharge operation. It is possible to grasp the remaining amount of ready-mixed concrete inside. In addition, even an inexperienced worker can easily grasp the amount of ready-mixed concrete remaining, and the current amount of ready-mixed concrete in the mixer drum 2 displayed on the display unit 50 can be easily monitored by the on-site supervisor at the casting site. It is possible to easily report the remaining amount of ready-mixed concrete by showing the In addition, it is possible to prevent variations in grasping of the remaining amount of ready-mixed concrete in the mixer drum 2 due to differences in operator experience.

The ready-mixed concrete amount estimation apparatus 100 further includes a display unit 50 that displays the current ready-mixed concrete amount in the mixer drum 2 estimated by the controller 30 .

In this configuration, the current amount of ready-mixed concrete in the mixer drum 2 estimated by the controller 30 is displayed on the display section 50 . A worker can grasp the remaining amount of ready-mixed concrete in the mixer drum 2 without interrupting the discharge work by seeing the current amount of ready-mixed concrete in the mixer drum 2 displayed on the display part 50.例文帳に追加can be done.

The ready-mixed concrete amount estimation apparatus 100 further includes a transmission unit 60 capable of transmitting the current ready-mixed concrete amount in the mixer drum 2 estimated by the controller 30 to the outside.

In this configuration, the current amount of ready-mixed concrete in the mixer drum 2 estimated by the controller 30 is transmitted by the transmitter 60 to the outside such as a concrete plant. For this reason, for example, the current amount of ready-mixed concrete in the mixer drums 2 of the plurality of mixer trucks 10 can be grasped in real time at the concrete plant, and the ready-mixed concrete can be efficiently delivered to the work site without excess or deficiency. As a result, the amount of ready-mixed concrete discarded is reduced, and the delivery efficiency of the mixer truck 10 is improved, so that the production cost and delivery cost of the ready-mixed concrete can be reduced.

In addition, the storage unit 31 stores in advance the trend of change in the sinking amount of the cradle unit 1 that changes according to the amount of fresh concrete loaded in the mixer drum 2 , and the estimation unit 33 stores the estimated amount of the inside of the mixer drum 2 . correct the current amount of ready-mixed concrete based on the change trend.

In this configuration, the current amount of ready-mixed concrete in the mixer drum 2 estimated by the estimating unit 33 is corrected based on the trend of change in the sinking amount of the pedestal unit 1 that changes according to the amount of ready-mixed concrete loaded in the mixer drum 2. be. By correcting the estimated amount Vn based on the changing tendency of the subsidence amount, which differs from vehicle to vehicle due to the characteristics of the shock absorber and the like, it is possible to improve the accuracy of estimating the amount of ready-mixed concrete in the mixer drum 2 .

Further, the distance sensor 20 is provided at least at a position where it is possible to detect the sinking amount of the cradle 1 on the side where the ready-mixed concrete is biased in the mixer drum 2 when the ready-mixed concrete is discharged from the mixer drum 2 .

In this configuration, the distance sensor 20 is provided at a position where the amount of sinking of the base 1 on the side where the ready-mixed concrete is biased within the mixer drum 2 can be detected. On the side where the ready-mixed concrete is biased in the mixer drum 2, the change in the sinking amount of the pedestal 1 with respect to a predetermined change in the amount of ready-mixed concrete is relatively large. By arranging the distance sensor 20 in the portion where the change in the sinking amount of the gantry 1 is relatively large, the accuracy of estimating the amount of ready-mixed concrete in the mixer drum 2 can be improved.

Further, the distance sensors 20 are provided in plurality at predetermined intervals in at least one of the front-rear direction and the width direction of the mixer truck 10 .

In this configuration, a plurality of distance sensors 20 are arranged at predetermined intervals in at least one of the longitudinal direction and the width direction of the mixer truck 10 . By estimating the amount of ready-mixed concrete in the mixer drum 2 based on the output values of the plurality of distance sensors 20 arranged in this manner, the estimation accuracy can be improved.

The ready-mixed concrete amount estimating apparatus 100 further includes an inclination sensor 22 that detects the inclination of the mixer truck 10, and the controller 30 corrects the correlation based on the inclination of the mixer truck 10 detected by the inclination sensor 22, The current amount of ready-mixed concrete in the mixer drum 2 is estimated based on the corrected correlation.

The storage unit 31 also stores the pre-loading tilt amount α1 detected by the tilt sensor 22 when the pre-loading sinking amount S1 is stored, and the tilt sensor 22 when the post-loading sinking amount S2 is stored. The detected post-loading tilt amount α2 is further stored, and the calculation unit 32 corrects the pre-loading sinking amount S1 with the pre-loading tilt amount α1 and corrects the post-loading sinking amount S2 with the post-loading tilt amount α2. Based on the corrected correlation, the estimation unit 33 converts the current sinking amount Sn detected by the distance sensor 20 to the current tilt amount αn detected by the tilt sensor 22. The current amount of ready-mixed concrete in the mixer drum 2 is estimated from the actual current subsidence amount Srn obtained by correction.

In these configurations, the correlation is corrected based on the tilt of the mixer truck 10 detected by the tilt sensor 22, and the current amount of ready-mixed concrete in the mixer drum 2 is estimated based on the corrected correlation. Therefore, even if the inclination of the stand part 1 is different when the ready-mixed concrete is loaded and when the ready-mixed concrete is discharged, the amount of the ready-mixed concrete in the mixer drum 2 can be estimated more accurately.

The mixer truck 10 also includes a ready-mixed concrete amount estimation device 100 .

In this configuration, the mixer truck 10 includes the ready-mixed concrete amount estimation device 100 configured as described above. Therefore, the amount of ready-mixed concrete in the mixer drum 2 of the mixer truck 10 can be easily grasped regardless of the operating state of the mixer drum 2 .

Although the embodiments of the present invention have been described above, the above embodiments merely show a part of application examples of the present invention, and the technical scope of the present invention is not limited to the specific configurations of the above embodiments. do not have.

DESCRIPTION OF SYMBOLS 100... Ready-mixed concrete amount estimation apparatus, 1... Mounting part, 2... Mixer drum, 10... Mixer vehicle, 20... Distance sensor (sinking detection part), 22... Tilt sensor ( Inclination detection unit), 30 controller, 31 storage unit, 32 calculation unit, 33 estimation unit, 40 input unit, 50 display unit, 60 Transmitter

Claims (9)

A ready-mixed concrete quantity estimating device for estimating the quantity of ready-mixed concrete in a mixer drum rotatably mounted on a mixer truck,
a sinking detection unit that detects an amount of sinking of a base that supports the mixer drum toward the ground;
a controller for estimating the amount of ready-mixed concrete in the mixer drum based on the sinking amount of the gantry detected by the sinking detection unit;
The controller is
Pre-loading sinking amount detected by the sinking detection unit when ready-mixed concrete is not loaded in the mixer drum, and sinking amount detected by the sinking detection unit when ready-mixed concrete is loaded in the mixer drum An amount of sinking after loading and an amount of ready-mixed concrete put into the mixer drum during the period from when the amount of sinking before loading is detected until when the amount of sinking after loading is detected are calculated in the mixer drum. a storage unit that stores each time ready-mixed concrete is thrown into the
Each time ready-mixed concrete is charged into the mixer drum, the amount of sinking of the base section and the amount of sinking of the mixer drum are calculated based on the amount of sinking before loading, the amount of sinking after loading, and the amount of sinking stored in the storage unit . a calculation unit that calculates the correlation between the amount of ready-mixed concrete in the mixer drum each time the ready-mixed concrete is put into the mixer drum ;
The current amount of ready-mixed concrete in the mixer drum is calculated from the current subsidence amount detected by the subsidence detection unit based on the correlation calculated by the calculation unit each time the ready -mixed concrete is charged into the mixer drum. and an estimating unit for estimating the amount of ready-mixed concrete. A ready-mixed concrete quantity estimating device for estimating the quantity of ready-mixed concrete in a mixer drum rotatably mounted on a mixer truck,
a sinking detection unit that detects an amount of sinking of a base that supports the mixer drum toward the ground;
a controller for estimating the amount of ready-mixed concrete in the mixer drum based on the sinking amount of the gantry detected by the sinking detection unit;
The controller is
Pre-loading sinking amount detected by the sinking detection unit when ready-mixed concrete is not loaded in the mixer drum, and sinking amount detected by the sinking detection unit when ready-mixed concrete is loaded in the mixer drum A memory for storing an amount of sinking after loading and an amount of ready-mixed concrete put into the mixer drum from when the amount of sinking before loading is detected until when the amount of sinking after loading is detected. Department and
a computing unit that computes the correlation between the subsidence amount of the base unit and the amount of ready-mixed concrete in the mixer drum based on the pre-loading subsidence amount, the post-loading subsidence amount, and the input amount;
an estimating unit for estimating the current amount of ready-mixed concrete in the mixer drum from the current sinking amount detected by the sinking detection unit based on the correlation,
The storage unit stores in advance a trend of change in the sinking amount of the pedestal that changes according to the amount of ready-mixed concrete loaded in the mixer drum,
The ready-mixed concrete amount estimation device, wherein the estimation unit corrects the estimated current amount of ready-mixed concrete in the mixer drum based on the change tendency. A ready-mixed concrete quantity estimating device for estimating the quantity of ready-mixed concrete in a mixer drum rotatably mounted on a mixer truck,
a sinking detection unit for detecting an amount of sinking of a base supporting the mixer drum toward the ground;
a controller for estimating the amount of ready-mixed concrete in the mixer drum based on the sinking amount of the gantry detected by the sinking detector;
a tilt detection unit that detects the tilt of the mixer vehicle,
The controller is
Pre-loading sinking amount detected by the sinking detection unit when ready-mixed concrete is not loaded in the mixer drum, and sinking amount detected by the sinking detection unit when ready-mixed concrete is loaded in the mixer drum A memory for storing an amount of sinking after loading and an amount of ready-mixed concrete put into the mixer drum from when the amount of sinking before loading is detected until when the amount of sinking after loading is detected. Department and
a computing unit that computes the correlation between the subsidence amount of the base unit and the amount of ready-mixed concrete in the mixer drum based on the pre-loading subsidence amount, the post-loading subsidence amount, and the input amount;
an estimating unit for estimating the current amount of ready-mixed concrete in the mixer drum from the current sinking amount detected by the sinking detection unit based on the correlation,
correcting the correlation based on the tilt of the mixer truck detected by the tilt detector, and estimating the current amount of ready-mixed concrete in the mixer drum based on the corrected correlation. Concrete amount estimation device. The storage unit stores the tilt amount before loading detected by the tilt detection unit when the amount of sinking before loading is stored, and the tilt detection unit detects the amount of sinking after loading when the amount of sinking after loading is stored. and the post-loading tilt amount that has been set are further stored,
The calculating unit corrects the correlation by correcting the amount of sinking before loading with the amount of inclination before loading and correcting the amount of sinking after loading with the amount of inclination after loading,
The estimating unit corrects the current amount of subduction detected by the subsidence detection unit by the current amount of tilt detected by the tilt detection unit based on the corrected correlation. 4. The apparatus for estimating the amount of ready-mixed concrete according to claim 3, wherein the present amount of ready-mixed concrete in the mixer drum is estimated from the present sinking amount. The ready-mixed concrete amount estimation apparatus according to any one of claims 1 to 4, further comprising a display section for displaying the current amount of ready-mixed concrete in the mixer drum estimated by the controller. 6. The ready-mixed concrete amount estimating apparatus according to any one of claims 1 to 5, further comprising a transmitting unit capable of transmitting the current ready-mixed concrete amount in the mixer drum estimated by the controller to the outside. The sinking detection unit is provided at least at a position where it is possible to detect the amount of sinking of the pedestal on the side where the ready-mixed concrete is biased in the mixer drum when the ready-mixed concrete in the mixer drum is discharged. The ready-mixed concrete amount estimation device according to any one of claims 1 to 6. 8. The method according to any one of claims 1 to 7, wherein a plurality of said sinking detectors are arranged at predetermined intervals in at least one of the longitudinal direction and the width direction of said mixer vehicle. The apparatus for estimating the amount of ready-mixed concrete described. A mixer truck comprising the ready-mixed concrete amount estimating device according to any one of claims 1 to 8.

Images