JP2014210625A - Grounding detection mechanism for outrigger of crane, overturning prevention controller for crane and overturning prevention system for crane - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a grounding detection mechanism for outriggers which is suitable for small cranes having a small lifting load, has an inexpensive configuration and determines the floating state of individual outriggers accurately.SOLUTION: A grounding detection mechanism 30 for outriggers of a crane 1 detects the grounding state of four outriggers 5 fitted to a traveling body 2 equipped with a crane boom 4 and includes four compression coil springs 34 which are stretchable according to a load applied to individual outriggers 5 and four stroke sensors 32 which detect stretch amounts of the individual compression coil springs 34. Stretch amounts of the compression coil springs which stretch according to a load applied to the outriggers 5 are detected by using the stroke sensors 32. Since displacement magnitudes are detected, instead of direct detection of a load, the grounding detection mechanism 30 can have a simple structure and be configured at low costs.

Description

  The present invention relates to an outrigger ground contact detection mechanism for detecting a ground contact state of an outrigger in order to prevent a crane from toppling over. The present invention also relates to a crane overturn prevention control device that prevents the crane from overturning by determining the lifted state of the outrigger based on the output from the ground contact detection mechanism of the outrigger. Furthermore, the present invention relates to a crane overturn prevention system including an outrigger contact detection mechanism and a crane overturn prevention control device.

  As a crane, a crane boom such as a knuckle boom is mounted on a traveling body made of a crawler, and in crane work, a structure in which the traveling body is fixed by projecting outriggers from four corners of the traveling body is known. . Such cranes include small cranes having a lifting load of less than 1 ton. Cranes with a lifting load of less than 1 ton are not required by law to install a load lifting limiter such as a moment limiter. However, even for small cranes, it is the manufacturer's responsibility to prevent falls during crane operation.

  Here, as the detection of the lifted state of the outrigger in a crane having a lifting load of 1 ton or more and the fall prevention mechanism, the one disclosed in Patent Document 1 is known. In the mechanism disclosed herein, a load cell is attached to each outrigger, and a load applied to each outrigger by each load cell is detected. Further, the loads acting on adjacent outriggers are summed, and the minimum value of the total value is compared with a predetermined comparison value to prevent the crane from falling over due to the lift of the outriggers.

JP 2004-307188 A

  In a conventional crane overturn prevention device, a load (load) applied to each outrigger is detected, and the lifted state of each outrigger is determined based on the detected load. As a fall prevention system incorporated into a small crane having a lifting load of less than 1 ton, it is desirable that the lifted state of each outrigger can be accurately determined by an inexpensive process and simple processing control. In addition, it is desirable that an appropriate fall prevention measure can be taken in various control forms in accordance with the floating state of each outrigger.

  In view of these points, an object of the present invention is to propose a grounding detection mechanism for an outrigger of a crane that can accurately determine the lifting state of each outrigger with an inexpensive configuration suitable for a small crane with a small lifting load. is there.

  Another object of the present invention is to propose a crane tipping prevention control device that can prevent the crane from tipping over in accordance with the floating state of each outrigger based on the output of the new ground contact detection mechanism.

  Another object of the present invention is to propose a crane tipping prevention system including such a new ground contact detection mechanism and tipping prevention control device.

In order to solve the above problems, the present invention provides:
A grounding detection mechanism for a crane outrigger that detects a grounding state of four outriggers attached to a traveling body equipped with a crane boom,
Four elastic members capable of expanding and contracting according to the load acting on each of the outriggers;
Four linear displacement sensors (stroke sensors) for detecting the amount of expansion and contraction of each of the elastic members;
It is characterized by having.

  In the ground contact detection mechanism according to the present invention, a linear displacement sensor (stroke sensor) is used to detect the expansion / contraction amount (linear displacement amount) of the elastic member that expands and contracts according to the load acting on each of the outriggers. Since the amount of displacement is detected instead of detecting the load directly, the ground contact detection mechanism can be configured with a simple structure at a low cost.

  In the present invention, each outrigger is provided with an outrigger cylinder for raising and lowering the outrigger up and down around a raising and lowering pin attached horizontally to the traveling body. Each of the outrigger cylinders can swing up and down around a horizontal connecting pin attached to the traveling body, and can slide within a certain range in the direction of the central axis of the outrigger cylinder perpendicular to the horizontal connecting pin. And connected to the traveling body.

  Furthermore, each of the elastic members is mounted between each of the outrigger cylinders and the traveling body so as to be extendable and contractable in the sliding direction of the outrigger cylinders. Each of the linear displacement sensors includes a sensor main body and a linear displacement detecting telescopic rod that protrudes from the sensor main body in a stretchable state. In a state where the axis of the outrigger cylinder extends in the sliding direction, the sensor main body is attached to the outrigger, and the telescopic rod is connected to the traveling body.

  In this way, the telescopic rod is pushed into the sensor body as the load acting on the outrigger increases. A detection signal representing the push amount is output from the linear displacement sensor.

Next, the present invention provides a crane overturn prevention control device that performs the overturn prevention control of the crane based on the output from each of the linear displacement sensors of the ground detection mechanism of the outrigger configured as described above.
A lift determination unit for determining the lift state of the outrigger;
Based on the determination result by the lifting determination unit, an operation regulating unit that regulates the operation of the crane boom so that the crane does not fall down,
A display unit comprising a display screen for displaying the floating state and the content of operation restriction by the operation restriction unit;
It is characterized by having.

  In this case, the pushing amount of the telescopic rod of the linear displacement sensor when the outrigger cylinder is farthest from the traveling body side in the sliding direction is 0%, and the outrigger cylinder is closest to the traveling body in the sliding direction. The push-in amount of the telescopic rod of the linear displacement sensor is 100%, the two adjacent outriggers are the first and second outriggers, and the linear displacement sensors attached to the first and second outriggers are the first and second linear displacements. When the sensor is used, the crane can be prevented from falling over as follows.

  That is, the lift determination unit determines that the amount of push of the second linear displacement sensor is in a state where the push amount of the first linear displacement sensor is A% (for example, 30%) or less during the turning operation of the crane boom in the left-right direction. When it becomes B% (for example, 50%) or less larger than this, it is determined that the outrigger has floated. Further, during the crane boom raising operation, the pushing amount of the second linear displacement sensor is the same as C when the pushing amount of the first linear displacement sensor is less than C% (for example, 70%) greater than B%. When it becomes less than% (for example, 70%), it is determined that the outrigger has floated. Further, during the crane boom down operation or extension operation, the push amount of the second linear displacement sensor is in a state where the push amount of the first linear displacement sensor is less than D% (for example, 90%) greater than B%. Is similarly D% (for example, 90%) or less, it is determined that the outrigger has floated. The operation restricting unit forcibly stops or restricts the operation of the crane boom being operated when the lift determining unit determines that the crane boom has been lifted.

  If the crane boom operation changes, the risk of the crane falling will change accordingly. In particular, when the crane boom is bent down and extended, the crane may fall over even if the outriggers are slightly lifted. In the present invention, the criterion for determining the lifting state of each outrigger is changed according to the operation mode of the crane boom. Therefore, it is possible to reliably prevent the crane from falling over regardless of the operation form of the crane boom.

  In the crane overturn prevention control device of the present invention, the display unit displays a crane image on the display screen for displaying the crane traveling body, the four outriggers, and the contour shape of the crane boom in a predetermined color. Each of the outriggers on the crane image is changed to a different display color when the outrigger falls into a lifted state, and the crane boom on the crane image is changed to a different display color when the operation of the crane boom is restricted. It is trying to display.

  According to the present invention, since the overturn prevention control state is displayed in an extremely easy-to-understand manner for the crane operator, it is possible to know the lifting state of each outrigger and the operation restriction state of the crane boom by simply looking at the display screen.

  Next, a crane overturn prevention system according to the present invention includes a ground displacement detection mechanism having a linear displacement sensor capable of accurately detecting a lifted state of each outrigger with a simple structure, and a crane boom operation mode based on the ground contact state. And a fall prevention control device having the above-described configuration that performs various fall prevention controls according to the above. Therefore, the inexpensive system configuration can reliably prevent the crane from tipping over regardless of the operation form of the crane boom.

It is a front view which shows the crane to which this invention is applied. It is explanatory drawing which shows an example in the state during the operation | work of the crane of FIG. It is explanatory drawing which shows a motion of the outrigger of the crane of FIG. It is the partial front view, partial bottom view, and partial side view which show the attachment part of the linear displacement sensor in the outrigger of the crane of FIG. It is a schematic block diagram which shows the control system of the crane of FIG. It is explanatory drawing which shows the example of the display screen of the operation part of the crane of FIG. It is explanatory drawing which shows the example of the display screen of the operation part of the crane of FIG.

  Below, with reference to drawings, an embodiment of a crane incorporating a fall prevention system to which the present invention is applied will be described.

(overall structure)
FIG. 1 is a front view showing a crane according to the present embodiment, and FIG. 2 is a schematic perspective view showing an example of a state during the crane operation. The crane 1 includes a traveling body 2 made of a crawler. A boom swivel 3 is mounted on the traveling body 2, and a knuckle boom type crane boom 4 is attached to the boom swivel 3. Further, four outriggers 5 (1) to 5 (4) (hereinafter collectively referred to as “outrigger 5”) are attached to the four corners of the traveling body 2. An operating lever 6 of the traveling body 2 is disposed at one end of the traveling body 2, and a control panel 7 is mounted at the other end of the traveling body 2.

  The crane boom 4 includes a first boom 8 and a second boom 9, and a rear end portion of the first boom 8 is attached to the boom swivel 3 so as to be able to rise and fall around a horizontal pin (not shown). The swivel base 3 is swung around the vertical axis, and the first boom 8 is swung in the left-right direction. A pair of hoisting cylinders 10 are bridged between the boom swivel base 3 and the first boom 8, and the hoisting operation of the first boom 8 is performed by extending and retracting the hoisting cylinders 10. The knuckle arm joint mechanism 11 is connected between the front end portion of the first boom 8 and the rear end portion of the second boom 9. When the cylinder 12 of the knuckle arm joint mechanism 11 is expanded and contracted, the second boom 9 can be raised and lowered with respect to the first boom 8. The second boom 9 is a multistage boom, and can extend and contract in its axial direction.

  The outrigger 5 is turned outward from the retracted state shown in FIG. 1, and in this state, the outrigger 5 is projected to lift the traveling body 2 from the ground contact surface. Thereby, the crane 1 is fixed in a stable state. FIG. 2 shows an example of this state. In this state, the crane boom 4 is raised and lowered, and various crane operations are performed.

  3A and 3B are explanatory views showing the movement of the outrigger 5, and FIG. 3A shows a state in which the outrigger 5 in the retracted state (see FIG. 1) is turned and turned outward, and FIGS. ) Shows three forms with the outrigger 5 overhanging.

  The outrigger 5 includes a first arm 13, a second arm 14, and an outrigger cylinder 15. The second arm 14 is connected to the distal end portion 13a of the first arm 13 so as to be rotatable about the horizontal connection pin 16. The second arm 14 is a two-stage arm, and as shown in FIGS. 3B and 3C, the inner arm 14B can be extended from the tip of the outer arm 14A. A grounding plate 17 is attached to the distal end portion 14a of the inner arm 14B via a swing pin 17a.

  In the traveling body 2, rotating shafts 19 that can be rotated around a vertical axis are attached to the four corners of the upper surface of the traveling body frame 18. A bracket 20 is attached to the rotating shaft 19 so as to project laterally and upward. A rear end portion 13b of the first arm 13 is connected to a portion of the bracket 20 that protrudes to the side via a horizontally disposed undulation pin 21 so as to be swingable in the vertical direction.

  The outrigger cylinder 15 is bridged between a portion projecting upward in the bracket 20 of the rotating shaft 19 and the bracket 20 attached to the distal end portion 13 a of the first arm 13. That is, the rear end of the cylinder body 15 a of the outrigger cylinder 15 is connected to the bracket 20 via the horizontal connection pin 22, and the tip of the telescopic rod 15 b of the outrigger cylinder 15 is connected to the bracket 20 via the horizontal connection pin 23. Has been.

  Here, the outrigger 5 is provided with a grounding detection mechanism 30 for detecting the floating state. The ground contact detection mechanism 30 is assembled between the rear end portion of the cylinder body 15a of the outrigger cylinder 15 and the horizontal connection pin 22 supported by the bracket 20 on the traveling body side.

(Grounding detection mechanism)
4A, 4B, and 4C are a front view, a bottom view, and a side view showing the ground contact detection mechanism 30, respectively. The grounding detection mechanism 30 includes a mechanism cover 31, a stroke sensor 32 that is a linear displacement sensor attached to the mechanism cover 31, a connecting bar 33, and a compression coil spring 34.

  The rear end portion of the cylinder body 15a of the outrigger cylinder 15 to which these parts are attached is configured as follows. An upper plate 36, a lower plate 37, and an end plate 38 are fixed to the rear end of the cylinder body 15a so as to surround the dog 35 attached to the horizontal connecting pin 22 from the upper and lower sides and the rear side. In the direction along the axis 15 </ b> A of the outrigger cylinder 15, the distance between the rear end surface 15 c of the cylinder body 15 a and the end plate 38 is wider than the thickness of the dog 35. Therefore, the outrigger cylinder 15 can slide in the direction of the axis 15 </ b> A with respect to the dog 35 attached to the horizontal connecting pin 22. A range until the end surface 15c comes into contact with the dog 35 is a slide range.

  The compression coil spring 34 of the ground detection mechanism 30 is mounted between the dog 35 and the rear end face 15c of the cylinder body 15a so as to be extendable and contractible in the direction of the axis 15A. The connecting bar 33 extends in a direction orthogonal to the axis 15 </ b> A through a circular through hole 37 a formed in the lower plate 37. The upper end of the connection bar 33 is fixed to the dog 35, and the connection bar 33 is always in a fixed position. The lower part of the connecting bar 33 protruding downward from the lower plate 37 is covered with a mechanism cover 31 fixed to the lower plate 37. A stroke sensor 32 is disposed in the mechanism cover 31 in a direction along the axis 15A. The tip of the telescopic rod 32a of the stroke sensor 32 is in contact with the connecting bar 33 in an orthogonal state.

  When the outrigger cylinder 15 is extended to extend the outrigger 5, a load acts on the outrigger 5. The outrigger cylinder 15 is slidable within a predetermined range in the direction of the axis 15 </ b> A (a direction perpendicular to the horizontal connection pin 22) with respect to the dog 35 attached to the horizontal connection pin 22. When a load larger than the spring force by the compression coil spring 34 is applied, the outrigger cylinder 15 slides back along the axis 15A according to the magnitude of the applied load. The stroke sensor 32 also moves in the direction of the axis 15A together. On the other hand, the connecting bar 33 attached to the dog 35 is in a fixed position.

  Therefore, as the outrigger cylinder 15 moves, the telescopic rod 32 a of the stroke sensor 32 is pushed by the connecting bar 33. The stroke sensor 32 outputs a detection signal having a voltage value corresponding to the push-in amount (linear displacement amount) of the telescopic rod 32a. If the outrigger 5 is lifted during the crane operation, the load acting on the outrigger 5 is reduced, so that the grounding state of each outrigger 5 (1) to 5 (4) based on the output from the stroke sensor 32 of each outrigger ( Can be discriminated.

(Control system)
FIG. 5 is a schematic block diagram showing a control system of the crane 1. The control system is mainly composed of a control panel 7 provided with a computer. The control unit of the control panel 7 includes a travel control unit 41 of the traveling body 2, an outrigger control unit 42 that controls the operation of the outrigger 5, a crane boom control unit 43 that controls the operation of the crane boom 4, and the grounding of the outrigger 5. A fall prevention control unit 44 that controls the fall prevention of the crane 1 based on the state is included. An operation unit 46 having a display screen 45 is connected to the control panel 7. Display control of the display screen 45 is performed by the display control unit 49 of the control panel 7. Since the control operations of the traveling control unit 41, the outrigger control unit 42, and the crane boom control unit 43 are the same as those of a general crane, the description thereof is omitted.

  The fall prevention control unit 44, based on the output from each of the stroke sensors 32 of the ground contact detection mechanism 30, a lift determination unit 47 that determines the lift state of each of the outriggers 5 (1) to 5 (4), and a lift determination unit 47. Is provided with an operation restricting section 48 that restricts the operation of the crane boom 4 so that the crane 1 does not fall over. On the display screen 45 of the operation unit 46, the detected floating state of each of the outriggers 5 (1) to 5 (4) and the content of the operation restriction by the operation restriction unit 48 are displayed. The control panel 7 including the fall prevention control unit 44 and the operation unit 46 constitute a fall prevention device, and the fall prevention device and the ground contact detection mechanism 30 constitute a fall prevention system.

  An example of the control operation of the fall prevention control unit 44 of this example will be described. Here, the pushing amount of the telescopic rod 32a of the stroke sensor 32 in a state where no load is applied to the outrigger cylinder 15 (when it is farthest from the horizontal connecting pin 22 side on the traveling body side in the direction of the axis 15A) is 0%. The pushing amount of the telescopic rod 32a in a state where the rear end face 15c of the outrigger cylinder 15 is in contact with the dog 35 is 100%. Two adjacent outriggers are referred to as first and second outriggers 5A and 5B, and the stroke sensors 32 attached to the first and second outriggers 5A and 5B are referred to as first and second stroke sensors 32A and 32B. .

  During the turning operation of the crane boom 4 in the left-right direction, the lift determination unit 47 is configured such that the pushing amount of the second stroke sensor 32B is B while the pushing amount of the first stroke sensor 32A is A%, for example, 30% or less. %, For example, 50% or less, it is determined that the sides of these outriggers 5A and 5B are in a lifted state. During the raising operation of the crane boom 4, the lifting judgment criterion is made stricter, and when the pushing amount of the first stroke sensor 32A is C%, for example, 70% or less, the pushing amount of the second stroke sensor 32B is also 70. If it is less than or equal to%, it is determined that the outriggers 5A and 5B have been lifted. Further, during the operation of lowering or extending the crane boom 4, the lift determination criterion is made strictest, and the second stroke sensor 32 </ b> B of the second stroke sensor 32 </ b> B is set in a state where the pushing amount of the first stroke sensor 32 </ b> A is D%, for example, 90% or less. When the pushing amount is similarly 90% or less, it is determined that the outriggers 5A and 5B have been lifted.

  In addition, the value of each pushing amount for the above-described lifting determination is an example, and is not limited to these values. Appropriate values may be set by simulation with an actual machine. In addition, it is only necessary that the value of each push-in amount for lifting determination can be set and changed via the operation unit 46. Further, when a winch or wire is mounted, the lifting determination may be performed even during the winch winding operation.

  When the lift determining unit 47 determines that the crane 1 has fallen into the lifted state, the operation restricting unit 48 outputs a stop signal for forcibly stopping the operation of the crane boom 4 being operated to the crane boom control unit 43. To do. When receiving the stop signal, the crane boom control unit 43 forcibly terminates the operation being performed. Thereafter, for example, a recovery operation for eliminating the lifting is displayed on the display screen 45. When the recovery operation is performed by the operator and the lifted state is resolved, the crane boom control unit 43 returns to the normal standby state.

  Further, when the lift determination unit 47 determines that the lift state has occurred, the fact that the lift state has occurred is displayed on the display screen 45 of the operation unit 46. Further, a message indicating that the operation of the crane boom 4 has been forcibly stopped (a message indicating that the operation has been restricted) is displayed.

(Display screen example)
6 and 7 are explanatory diagrams showing the display form of the display screen 45 of the operation unit 46. FIG. FIG. 6A is an explanatory diagram showing a screen when the crane 1 is started. On the display screen 50 at the time of starting, five switches 51 to 55 and 56 to 60 are displayed on the left and right, respectively. In the rectangular display area 61 between them, a manufacturer's logo mark or the like is displayed. The display screen 50 at the time of start is switched to a traveling mode screen 62 shown in FIG. 6B and a crane mode screen 63 shown in FIG. 6C by operating the operation lever 6 of the crane 1.

  In the crane mode screen 63, icons and display lamps representing functions assigned to these are displayed in portions adjacent to the switches 51 to 60 in the display area 61. For example, the button 51 is a stop / start switch for a driving engine mounted on the traveling body 2, and the lamp is green (shown in gray in the figure) when the engine is operating, and red (in the figure, when the engine is stopped). Is indicated by diagonal lines.) Is displayed. The button 52 is a winch / wire multiplier selection mode switch. When this button is operated, a winch / wire multiplier selection mode screen shown in FIG. The switch 53 is a service mode selection switch. When this switch 53 is operated, the screen switches to a service mode screen shown in FIG. The switch 54 is a work range regulation setting mode switch, and the switch 55 is a sub-boom (second boom 9) storage switch.

  The switch 56 on the right side of the screen is a sub boom (second boom 9) operation changeover switch, and the switch 57 is a main boom (first boom 8) operation changeover switch. The switch lamp on the selected side is displayed in green, for example. The switch 58 is an outrigger individual operation mode selection switch, and when this switch is operated, the screen switches to an outrigger individual operation mode screen shown in FIG. The switches 59 and 60 are outrigger batch operation switches.

  Further, in the crane mode screen 63, the upper left of the display area 61 is a time display area 64, and the lower side is a display area 65 and a level display area 66 in which the planar shape of the crane 1 is displayed. Above these right sides is a fuel gauge display area 67, and on the right side is a display area 68 representing a winch / wire hooked state.

  In the crane mode screen 63, as described above, the lifting determination unit 47 of the fall prevention control unit 44 determines the grounding state (lifting state) of the outrigger 5 during the crane boom operation (crane work). In the display area 65, the planar shape of the crane 1 is displayed. For example, as shown in FIG. 6D, a crane that displays the traveling body 2 of the crane 1, the four outriggers 5 (1) to 5 (4), and the contour shape of the crane boom 4 in a predetermined color, for example, green. An image is displayed. When the floating state is detected, the lamp displayed on the corresponding outrigger on the crane image is changed from green to, for example, red.

  Next, in the outrigger individual operation mode screen 70 shown in FIG. 7A, the switches 52 and 53 become the operation switches for the outrigger 5 (1), the switches 54 and 55 become the operation switches for the outrigger 5 (2), and the switch 57 , 58 serve as operation switches for the outrigger 5 (3), and switches 59, 60 serve as operation switches for the outrigger 5 (4). The switch 56 is a home switch and is operated when switching to the crane mode (FIG. 6C). In the outrigger grounding / overhang display area 65, as shown in FIG. 6D, the display changes depending on the grounding state and the overhanging state of the outrigger 5. The upper side of the level display area 66 is a display area 68 for winch mode display, application display, and the like.

  On the service mode display screen 80 shown in FIG. 7B, a tool mark indicating that the service mode is in the display area 61 is displayed. The switches 52 to 55 are a display adjustment mode switch, a language switching mode switch, a radio control adjustment mode switch, and a calibration mode switch, respectively. The switches 57 to 60 are an instruction manual browsing mode switch, a shop manual browsing mode switch, an error / history browsing mode switch, and a consumables browsing mode switch.

  In the winch / wire multiplier selection mode screen 90 shown in FIG. 7C, a hook mark indicating the mode is displayed in the display area 61. The switches 52 to 54 are switches for switching the number of main boom (first boom 8) wire hooks (four hooks, two hooks, and one hook). The switches 57 and 58 are sub boom (second boom 9) wire number changing switches (fixed hooks, single hooks). By the switching operation by these, the shape of the crane 1 displayed in the display area 68 changes. For example, when the four main boom hooks are selected, the shape changes to the shape shown in FIG. 7D, and when the one sub boom is selected, the shape changes to the shape shown in FIG.

1 crane, 2 traveling body, 3 boom swivel, 4 crane boom,
5 (1) -5 (4) Outrigger, 6 operation lever, 7 control panel, 8 first boom,
9 Second boom, 10 hoisting cylinder, 11 knuckle arm joint mechanism,
13 1st arm, 13a tip part, 13b back end part, 14 2nd arm,
14a tip, 14A outer arm, 14B inner arm,
15 outrigger cylinder, 15A axis, 15a cylinder body,
15b telescopic rod, 16 horizontal connecting pin, 17 ground plate, 18 traveling body frame,
19 rotating shaft, 20 bracket, 21 undulation pin, 22 horizontal connecting pin,
23 horizontal connection pin, 30 grounding detection mechanism, 31 mechanism cover,
32 stroke sensor, 32a telescopic rod, 33 connecting bar,
34 compression coil spring, 35 dog, 36 upper plate, 37 lower plate, 37a through hole,
38 end plates, 41 travel control unit, 42 outrigger control unit,
43 crane boom control unit, 44 fall prevention control unit, 45 display screen,
46 operation unit, 47 lift determination unit, 48 operation restriction unit, 49 display control unit,
50 display screen, 51-60 switches, 61 display area, 62 travel mode screen,
63 crane mode screen, 64 hour display area, 65 display area,
66 level display area, 67 fuel gauge display area, 68 display area,
70 Outrigger individual operation mode screen, 80 Service mode display screen,
90 winch / wire multiplier selection mode screen

Claims (6)

A grounding detection mechanism for a crane outrigger that detects a grounding state of four outriggers attached to a traveling body equipped with a crane boom,
Four elastic members capable of expanding and contracting according to the load acting on each of the outriggers;
Four linear displacement sensors (stroke sensors) for detecting the amount of expansion and contraction of each of the elastic members;
A grounding detection mechanism for an outrigger of a crane, characterized by comprising: Each of the outriggers has four outrigger cylinders that undulate up and down around a undulation pin attached horizontally to the traveling body;
Each of the outrigger cylinders can swing up and down around a horizontal connecting pin attached to the traveling body, and can slide within a certain range in the direction of the central axis of the outrigger cylinder perpendicular to the horizontal connecting pin. In the state, connected to the traveling body,
Each of the elastic members is mounted between each of the outrigger cylinders and the traveling body in a state in which the elastic members can extend and contract in the sliding direction of the outrigger cylinders,
Each of the linear displacement sensors includes a sensor main body and a telescopic rod for linear displacement detection that protrudes from the sensor main body in a stretchable state.
In the state where the telescopic rod extends in the sliding direction, the sensor body is attached to the outrigger,
The telescopic rod is connected to the traveling body,
The ground contact detection mechanism for an outrigger of a crane according to claim 1, wherein the telescopic rod is pushed into the sensor main body as the load acting on the outrigger increases. A lift determination unit that determines a lift state of the outrigger based on an output from each of the linear displacement sensors of the ground detection mechanism of the outrigger according to claim 1 or 2,
Based on the determination result by the lifting determination unit, an operation regulating unit that regulates the operation of the crane boom so that the crane does not fall down,
A display unit comprising a display screen for displaying the floating state and the content of operation restriction by the operation restriction unit;
A crane overturn prevention control device characterized by comprising: The pushing amount of the telescopic rod of the linear displacement sensor when the outrigger cylinder is farthest from the traveling body side in the sliding direction is 0%, and the outrigger cylinder is closest to the traveling body in the sliding direction. In this case, the pushing amount of the telescopic rod of the linear displacement sensor is 100%,
When the two adjacent outriggers are first and second outriggers, and the linear displacement sensors attached to the first and second outriggers are first and second linear displacement sensors,
The lift determination unit
During the turning operation of the crane boom in the left-right direction, when the pushing amount of the first linear displacement sensor is A% or less and the pushing amount of the second linear displacement sensor is B% or less, which is larger than A%, Judging that the outrigger has floated,
When the pushing amount of the first linear displacement sensor is equal to or less than C% in the state in which the pushing amount of the first linear displacement sensor is greater than B% during the raising operation of the crane boom, the outrigger Is determined to have fallen,
When the pushing amount of the first linear displacement sensor is equal to or less than D% in a state where the pushing amount of the first linear displacement sensor is greater than C% and equal to or less than D% during the crane boom down operation or extension operation. , It is determined that the outrigger has floated,
4. The crane overturn prevention control device according to claim 3, wherein the operation restricting unit restricts the operation of the crane boom during operation when the lift determining unit determines that the crane boom has fallen into the lifted state. 5.   The display unit displays, on the display screen, a crane image that displays a contour of the crane traveling body, the four outriggers, and the crane boom in a predetermined color, and the outriggers on the crane image are displayed. 5. Each of them is changed to a different display color when the outrigger falls into a lifted state, and the crane boom on the crane image is changed to a different display color when operation of the crane boom is restricted. Crane fall prevention control device. The ground contact detection mechanism of the outrigger of the crane according to claim 1 or 2,
The crane control device according to any one of claims 3 to 5,
A fall prevention system for a crane, characterized by comprising: