JP6859637B2 - Pressure booster for aerial work platforms - Google Patents

Description

The present invention relates to a pressure booster. More specifically, the present invention relates to a pressure booster for an aerial work platform that supplies boosted hydraulic oil to a flood control tool.

Conventionally, aerial work platforms are known in which a bucket on which an operator is boarded is provided at the tip of a telescopic boom. The aerial work platform is configured so that hydraulic oil can be supplied to hydraulic equipment such as hydraulic tools in the bucket. In aerial work platforms for electrical wiring work, hydraulic oil can be supplied to a hydraulic crimping tool, which is a hydraulic tool that connects power lines by crimping a sleeve for electrical wiring. In the aerial work platform configured in this way, a pressure boosting device for supplying the pressure boosted hydraulic oil is provided. For example, as described in Patent Document 1.

The pressure booster for aerial work platforms described in Patent Document 1 controls the pressure boosting cylinder by switching between the directional control valve on the upstream side and the directional control valve on the downstream side to boost the hydraulic pressure of the hydraulic oil. A pressure switch is connected to the pressure boosting oil chamber of the pressure boosting cylinder, and it is possible to detect whether or not the oil pressure in the pressure boosting oil chamber exceeds a predetermined pressure. The pressure switch and the directional control valve are connected to the control means, and when the pressure switch detects that the pressure exceeds a predetermined pressure, the directional control valve is switched to increase or decrease the hydraulic pressure of the hydraulic oil.

Japanese Unexamined Patent Publication No. 2014-20543

The pressure switch of the pressure booster described in Patent Document 1 can only determine whether the pressure value in the pressure boosting chamber (pressure boosting oil chamber) has reached a predetermined pressure, and can determine the maximum pressure or the maximum pressure in the pressure boosting chamber. It was not possible to grasp the time required to reach the pressure. Therefore, even if a problem occurs in the direction control valve, the hydraulic circuit, the hydraulic pump, or the like of the pressure booster, it may not be detected.
Therefore, an object of the present invention is to provide a pressure booster for aerial work platforms that can detect a defect in the pressure booster.

That is, the pressure booster for a high-place work vehicle is a pressure booster for a high-place work vehicle that supplies the hydraulic oil boosted by the pressure boost cylinder to the flood control tool, and has a pressure boosting chamber of the pressure boost cylinder. A supply oil passage connecting the hydraulic tool, a pressure boosting oil passage for guiding hydraulic oil to the head side oil chamber of the pressure boosting cylinder, and a depressurizing oil for guiding hydraulic oil to the rod side oil chamber of the pressure boosting cylinder. A state in which a road, an electromagnetic switching valve for preload connected to the supply oil passage, and a state of being connected to the pressure boosting cylinder and supplying hydraulic oil to the head side oil chamber of the pressure boosting cylinder through the pressure boosting oil passage. An electromagnetic switching valve for main pressure that can be switched between a state in which hydraulic oil is supplied to the rod-side oil chamber of the pressure boosting cylinder through the pressure reducing oil passage, and a pressure detection that detects the pressure in the pressure boosting chamber. Means, and the maximum pressure detected for each of a plurality of operations in the operation in which the hydraulic tool performs the main compression operation is stored, and the maximum value and the minimum value of the stored maximum pressure for each operation are stored. When the pressure difference is larger than the pressure threshold , or for each operation, the maximum pressure arrival time from the switching timing of the electromagnetic switching valve for preload or the electromagnetic switching valve for main pressure to reaching each maximum pressure. Is stored, and when the time difference between the longest value and the shortest value is larger than the time threshold among the stored maximum pressure arrival times, it is detected as a defect.

The pressure booster for aerial work platforms detects as a defect when the maximum pressure detected by the pressure detecting means is out of a predetermined pressure range .

In the pressure booster for aerial work platforms, the maximum pressure arrival time from the switching timing of the electromagnetic switching valve for preload or the electromagnetic switching valve for main pressure to reaching the maximum pressure is out of the predetermined time range. If there is, it will be detected as a defect .

The pressure booster for aerial work platforms detects as a defect when the respective maximum pressure arrival times from the plurality of switching timings to the arrival of the maximum pressure are out of the set predetermined time range. ..

According to the present invention, it is possible to determine whether the maximum pressure in the pressure boosting chamber and the time required to reach the maximum pressure are appropriate, and detect a defect in the pressure booster.

The side view which shows the whole structure of the aerial work platform which concerns on this invention. The figure which shows the hydraulic circuit of the pressure booster for the aerial work platform which concerns on this invention. The figure which shows the control structure of the pressure booster for aerial work platforms which concerns on this invention. The figure which shows the operation mode of the hydraulic tool connected to the pressure booster for the aerial work platform which concerns on this invention. The figure which shows the relationship between the pressure of a pressure boosting chamber and time in the caulking work of a hydraulic tool in the pressure booster for aerial work platforms which concerns on this invention. (A) A diagram showing the relationship between the maximum pressure in the pressure booster for aerial work platforms according to the present invention and a predetermined pressure range (b) Reaching the maximum pressure in the pressure booster for aerial work platforms according to the present invention. The figure which shows the relationship between time and a predetermined time range (c) figure which shows the relationship between the maximum pressure and the maximum pressure arrival time in the pressure booster for aerial work platforms according to the present invention. The flowchart which shows the control mode in the caulking work of the pressure booster for aerial work platforms which concerns on this invention. The flowchart which shows the control mode in the detection of the defect of the pressure booster for aerial work platforms which concerns on this invention. (A) A diagram showing the pressure difference between the maximum value and the minimum value of the maximum pressure detected for each work in the pressure booster for the aerial work platform according to the present invention. (B) The aerial work platform according to the present invention. The figure which shows the time difference between the longest value and the shortest value of the maximum pressure arrival time detected for each work in the pressure booster. The flowchart which shows the control mode of the 2nd Embodiment in the detection of the defect of the pressure booster for the aerial work platform which concerns on this invention. FIG. 5 is a flowchart showing a control mode for detecting a defect due to the maximum pressure of the pressure booster for an aerial work platform according to the present invention. The flowchart which shows the control mode of the detection of the defect by the maximum pressure arrival time of the pressure booster for aerial work platforms which concerns on this invention.

Hereinafter, the aerial work platform 1 according to the embodiment of the aerial work platform will be described with reference to FIG.

As shown in FIG. 1, the aerial work platform 1 is an aerial work platform for electrical wiring work in which the sleeve S is crimped using a hydraulic crimping tool 100 (see FIG. 2), which is a hydraulic tool, to connect power lines to each other. Is. The aerial work platform 1 has a vehicle 2 and an aerial work platform 6.

The vehicle 2 conveys the high-altitude work device 6. The vehicle 2 is provided with a driver's cab and a plurality of wheels 3, and is equipped with an engine 4 (see FIG. 2) as a power source. The vehicle 2 is configured to travel by transmitting the driving force of the engine 4 to the plurality of wheels 3. The vehicle 2 is provided with an outrigger 5. The outrigger 5 is composed of an overhang beam that can be extended by flood control on both sides of the vehicle 2 in the width direction and a hydraulic jack cylinder that can be extended in a direction perpendicular to the ground. The vehicle 2 can expand the workable range of the aerial work platform 1 by extending the outrigger 5 in the width direction of the vehicle 2 and grounding the jack cylinder.

The high-altitude work device 6 lifts the bucket 9 on which the worker is boarding to a high place. The aerial work device 6 includes a swivel table 7, a telescopic boom 8, a bucket 9, an undulating cylinder 10, and an operating device 11.

The swivel base 7 swivels the telescopic boom 8. The swivel base 7 is provided on the frame of the vehicle 2 via an annular bearing. The annular bearing is arranged so that its center of rotation is perpendicular to the installation surface of the vehicle 2. The swivel base 7 is rotatably configured with the center of the annular bearing as the center of rotation. Further, the swivel base 7 is configured to be rotated by a hydraulic swivel motor (not shown).

The telescopic boom 8 supports the bucket 9. The telescopic boom 8 is composed of a plurality of boom members. Each boom member is formed in a hollow cylindrical shape having polygonal cross sections similar to each other. Each boom member is formed in a size that can be inserted into the boom member in the order of the size of the cross-sectional area. The telescopic boom 8 is configured so that each boom member can move in the axial direction. That is, the telescopic boom 8 is configured to be telescopic by moving each boom member with a telescopic cylinder or the like (not shown). The telescopic boom 8 is provided so that the base end of the boom member can swing on the swivel base 7. Further, the telescopic boom 8 is configured to swing freely around the base end of the boom member with respect to the swivel base 7.

The bucket 9 is for securing a working space for an operator. The bucket 9 is configured so that an operator can get inside. The bucket 9 is supported by the tip of the telescopic boom 8 via a support mechanism 9a. The support mechanism 9a swings the bucket 9 in the elevation and horizontal directions by a hydraulic actuator (not shown).

The undulating cylinder 10 erects and lays down the telescopic boom 8 to maintain the posture of the telescopic boom 8. The undulating cylinder 10 is composed of a hydraulic cylinder. The base of the undulating cylinder 10 is swingably connected to the swivel base 7, and the rod tip is swingably connected to the telescopic boom 8. The undulating cylinder 10 erects or undulates the telescopic boom 8 by expanding and contracting the rod.

The operating device 11 operates the swivel base 7, the telescopic boom 8, the bucket 9, and the like. The operating device 11 is provided inside the vehicle 2 and the bucket 9. The operation device 11 is provided with a swivel telescopic operation tool for swiveling the swivel base 7, a swivel telescopic operation for expanding and contracting the telescopic boom 8, an undulating operation tool for performing the undulating operation of the telescopic boom 8, an engine start switch, and the like. Further, the operating device 11 is provided with a hydraulic switching operating tool 11a (see FIG. 3) for switching the hydraulic pressure of the hydraulic oil supplied to the hydraulic crimping tool 100. The hydraulic switching operating tool 11a switches the hydraulic oil to the hydraulic crimping tool 100 to a state in which the increased hydraulic oil can be supplied, and discharges the hydraulic oil from the hydraulic crimping tool 100.

Hereinafter, the pressure booster 12 included in the aerial work platform 1 will be described with reference to FIGS. 2 and 3.

As shown in FIG. 2, the pressure booster 12 boosts the oil pressure of the hydraulic oil supplied to the hydraulic crimping tool 100. The pressure boosting device 12 includes a pressure boosting cylinder 13, a pressure sensor 14, a preload electromagnetic switching valve (preload switching valve 17) which is a directional control valve, a relief valve 21, and a main pressure electromagnetic switching valve (direction control valve). It includes a main pressure switching valve 24), a pilot check valve 27, a hydraulic pump 28, and a control device 31 (see FIG. 3).

The pressure boosting cylinder 13 boosts the pressure of the hydraulic oil. The pressure boosting cylinder 13 is composed of a hydraulic cylinder provided with a bottomed cylindrical pressure boosting chamber 13a provided on the rod side. The pressure boosting cylinder 13 is configured such that the inner diameter of the pressure boosting chamber 13a is smaller than the inner diameter of the pressure boosting cylinder. A large-diameter piston 13d to which the rod 13f is connected is slidably inserted inside the pressure boosting cylinder. Inside the pressure boosting cylinder 13, a rod-side oil chamber 13b and a head-side oil chamber 13c are configured. A small-diameter piston 13e is slidably inserted inside the pressure boosting chamber 13a. In the pressure boosting cylinder 13, a small diameter piston 13e in the pressure boosting chamber 13a and a large diameter piston 13d in the pressure boosting cylinder 13 are connected via a rod 13f. In the pressure boosting cylinder 13, when hydraulic oil is supplied to the head side oil chamber 13c of the pressure boosting cylinder 13, the force generated in the large diameter piston 13d due to the pressure of the hydraulic oil is transmitted to the small diameter piston 13e in the pressure boosting chamber 13a. .. As a result, the pressure boosting cylinder 13 pressurizes the hydraulic oil in the pressure boosting chamber 13a by the force boosted by the area ratio of the large diameter piston 13d and the small diameter piston 13e.

A pressure sensor 14 is connected to the pressure boosting chamber 13a of the pressure boosting cylinder 13 as a pressure detecting means. The pressure sensor 14 can detect the pressure of the hydraulic oil in the pressure boosting chamber 13a in real time. The pressure sensor 14 is connected to the control device 31. Further, a supply oil passage 15 is connected to the pressure boosting chamber 13a of the pressure boosting cylinder 13. The supply oil passage 15 is provided with a joint 16 to which the hydraulic crimping tool 100 can be connected. As a result, the pressure boosting device 12 is configured so that the hydraulic oil boosted in the pressure boosting chamber 13a of the pressure boosting cylinder 13 can be supplied to the hydraulic crimping tool 100 connected to the joint 16 through the supply oil passage 15. ..

The preload electromagnetic switching valve (hereinafter, simply referred to as “preload switching valve 17”), which is a directional control valve, is a supply in which the pressure boosting chamber 13a of the pressure boosting cylinder 13 and the hydraulic crimping tool 100 are connected to each other. It switches the direction of the hydraulic oil supplied to the oil passage 15. A supply oil passage 15 is connected to one port of the preload switching valve 17 via a low pressure oil passage 18. A supply oil passage 15 is connected to the other port of the preload switching valve 17 via a preload oil passage 19. A hydraulic pump 28 is connected to the supply port of the preload switching valve 17 via a discharge oil passage 20. That is, the hydraulic oil is supplied to the preload switching valve 17 at the discharge pressure of the hydraulic pump 28 (hereinafter, simply referred to as “preload”). In the preload switching valve 17, one of one port and the other port is communicated with the supply port by moving a spool (not shown) by an electromagnet.

A relief valve 21 that controls the pressure of hydraulic oil to a set value or less is connected to the low pressure oil passage 18 connected to one port of the preload switching valve 17. In the relief valve 21, a branch oil passage branched from the low pressure oil passage 18 is connected to the inlet port, and a hydraulic oil tank 30 is connected to the outlet port. Further, the low pressure oil passage 18 is provided with a throttle 22 on the upstream side of the branch oil passage of the relief valve 21, and a check valve 23 on the downstream side. When the oil pressure of the hydraulic oil flowing through the low-pressure oil passage 18 reaches a set value, the relief valve 21 returns a part of the hydraulic oil flowing through the low-pressure oil passage 18 to the hydraulic oil tank 30 through the branch oil passage. That is, the oil pressure of the hydraulic oil flowing through the low pressure oil passage 18 is controlled by the relief valve 21 to a relief pressure Pa (hereinafter, simply referred to as “low pressure”) lower than the preload. Further, the flow rate of the hydraulic oil flowing through the low pressure oil passage 18 is limited to the relief flow rate of the relief valve 21 or less by the throttle 22. A check valve 23 is provided in the preload oil passage 19. The preload switching valve 17 is connected to the control device 31.

The preload switching valve 17 is in a state in which the low pressure oil passage 18 and the preload oil passage 19 are connected to the hydraulic oil tank 30 when the electromagnet is not excited (when the operation signal is not received from the control device 31). The spool is moved to position II. That is, the preload switching valve 17 is switched to a state in which the hydraulic oil discharged from the hydraulic pump 28 is not supplied to the supply oil passage 15. As a result, the pressure booster 12 does not supply hydraulic oil to the pressure boosting chamber 13a of the pressure boosting cylinder 13 and the hydraulic crimping tool 100 through the oil supply passage 15.

The preload switching valve 17 has a low-pressure oil passage when an electromagnet is excited so that one port and a supply port communicate with each other (when an operation signal for supplying low-pressure hydraulic oil is received from the control device 31). The spool is moved to the I position where 18 is connected to the discharge oil passage 20 and the preload oil passage 19 is connected to the hydraulic oil tank 30. That is, the preload switching valve 17 is switched to a state in which hydraulic oil is supplied to the supply oil passage 15 through the low pressure oil passage 18. As a result, the pressure booster 12 supplies the low pressure hydraulic oil to the pressure boosting chamber 13a of the pressure boosting cylinder 13 and the hydraulic crimping tool 100 through the supply oil passage 15. At this time, the flow rate of the hydraulic oil supplied to the pressure boosting chamber 13a of the pressure boosting cylinder 13 and the hydraulic crimping tool 100 is limited by the throttle 22 of the low pressure oil passage 18.

The preload switching valve 17 has a preload oil passage when the electromagnet is excited so that the other port and the supply port communicate with each other (when an operation signal for supplying the preload hydraulic oil is received from the control device 31). The spool is moved to position III in which 19 is connected to the discharge oil passage 20 and the low pressure oil passage 18 is connected to the hydraulic oil tank 30. That is, the preload switching valve 17 is switched to a state in which hydraulic oil is supplied to the supply oil passage 15 through the preload oil passage 19. As a result, the pressure booster 12 supplies the hydraulic oil of the preload to the pressure boosting chamber 13a of the pressure boosting cylinder 13 and the hydraulic crimping tool 100 through the supply oil passage 15.

The main pressure electromagnetic switching valve (hereinafter, simply referred to as “main pressure switching valve 24”), which is a directional control valve, switches the direction of the hydraulic oil supplied to the pressure boosting cylinder 13. A rod-side oil chamber 13b of the pressure boosting cylinder 13 is connected to one port of the main pressure switching valve 24 via a pressure reducing oil passage 25. The head side oil chamber 13c of the pressure boosting cylinder 13 is connected to the other port of the main pressure switching valve 24 via the pressure boosting oil passage 26. A hydraulic pump 28 is connected to the supply port of the main pressure switching valve 24 via a discharge oil passage 20. That is, hydraulic oil is supplied to the main pressure switching valve 24 with a preload. In the main pressure switching valve 24, one of one port and the other port is communicated with the supply port by moving a spool (not shown) by an electromagnet. The main pressure switching valve 24 is connected to the control device 31.

The main pressure switching valve 24 is in a state where the decompression oil passage 25 and the pressure boosting oil passage 26 are connected to the hydraulic oil tank 30 when the electromagnet is not excited (when the operation signal is not received from the control device 31). The spool is moved to a certain II position. That is, the main pressure switching valve 24 is switched to a state in which the hydraulic oil discharged from the hydraulic pump 28 is not supplied to the pressure boosting cylinder 13. As a result, the pressure boosting device 12 does not boost the hydraulic pressure of the hydraulic oil by the pressure boosting cylinder 13.

The main pressure switching valve 24 has a pressure reducing oil passage when an electromagnet is excited so that one port and a supply port communicate with each other (when an operation signal for reducing the hydraulic pressure of hydraulic oil is received from the control device 31). The spool is moved to the I position where 25 is connected to the discharge oil passage 20 and the pressure boosting oil passage 26 is connected to the hydraulic oil tank 30. That is, the main pressure switching valve 24 is switched to a state in which hydraulic oil is supplied to the rod-side oil chamber 13b of the pressure boosting cylinder 13 through the pressure reducing oil passage 25. As a result, the pressure boosting device 12 moves the small diameter piston 13e in the direction in which the volume of the pressure boosting chamber 13a increases to reduce the oil pressure of the hydraulic oil.

The main pressure switching valve 24 is used when the electromagnet is excited so that the other port and the supply port communicate with each other (when an operation signal for increasing the hydraulic pressure of the hydraulic oil is received from the control device 31). The spool is moved to position III in which the passage 26 is connected to the discharge oil passage 20 and the decompression oil passage 25 is connected to the hydraulic oil tank 30. That is, the main pressure switching valve 24 is switched to a state in which hydraulic oil is supplied to the head side oil chamber 13c of the pressure boosting cylinder 13 through the pressure boosting oil passage 26. As a result, the pressure booster 12 moves the small-diameter piston 13e in the direction in which the volume of the pressure boosting chamber 13a decreases to boost the hydraulic pressure of the hydraulic oil.

The pilot check valve 27 opens the oil passage. In the pilot type check valve 27, the supply oil passage 15 is connected to the inlet port, and the hydraulic oil tank 30 is connected to the outlet port. Further, the pilot type check valve 27 is configured so that the pilot hydraulic oil is supplied from the pressure reducing oil passage 25. When the main pressure switching valve 24 is switched to a state of supplying hydraulic oil to the rod side oil chamber 13b of the boosting cylinder 13, the pilot type check valve 27 is opened by supplying hydraulic oil for pilot from the decompression oil passage 25. To speak. The hydraulic oil in the pressure boosting chamber 13a connected to the supply oil passage 15 and the hydraulic oil in the hydraulic crimping tool 100 are returned to the hydraulic oil tank 30 through the pilot check valve 27. As a result, the pressure booster 12 is configured to be able to quickly discharge the hydraulic oil in the pressure boosting chamber 13a and the hydraulic oil in the hydraulic crimping tool 100.

The hydraulic pump 28 discharges hydraulic oil at a predetermined discharge pressure. The hydraulic pump 28 is driven by the engine 4. A preload switching valve 17 and a main pressure switching valve 24 are connected in parallel to the hydraulic pump 28. The hydraulic oil discharged from the hydraulic pump 28 is supplied to the preload switching valve 17 and the main pressure switching valve 24 through the discharge oil passage 20, respectively. A relief valve 29 for a hydraulic pump is provided in the discharge oil passage 20. The relief valve 29 for a hydraulic pump controls the oil pressure of the hydraulic oil discharged from the hydraulic pump 28 to a set value or less.

As shown in FIG. 3, the control device 31 controls the operation of the preload switching valve 17 and the main pressure switching valve 24 of the pressure boosting device 12. The control device 31 may actually have a configuration in which a CPU, ROM, RAM, HDD, etc. are connected by a bus, or may have a configuration including a one-chip LSI or the like. The control device 31 stores various programs and data for controlling the operation of the preload switching valve 17 and the main pressure switching valve 24. The control device 31 is provided in the vehicle 2.

The control device 31 is connected to the hydraulic switching operation tool 11a, and can acquire an operation signal from the hydraulic switching operation tool 11a.

The control device 31 is connected to the pressure sensor 14 of the pressure boosting chamber 13a, and can acquire the detected value of the oil pressure of the hydraulic oil in the pressure boosting chamber 13a detected by the pressure sensor 14.

The control device 31 is connected to the preload switching valve 17, and can selectively excite the electromagnet of the preload switching valve 17 to change the position of the spool of the preload switching valve 17.

The control device 31 is connected to the main pressure switching valve 24, and the electromagnet of the main pressure switching valve 24 can be selectively excited to change the position of the spool of the main pressure switching valve 24.

The control device 31 is connected to the tool operating tool 100c of the hydraulic crimping tool 100 via the connector 31a, and can acquire an operation signal from the hydraulic crimping tool 100.

The control device 31 is connected to an alarm device 32 provided as an alarm means. When the alarm device 32 detects a malfunction of the pressure booster 12 or the like, the alarm device 32 notifies the operator by issuing an alarm display or an alarm sound. The alarm device 32 is not limited to being composed of an alarm display or an alarm sound, as long as it can notify the operator of a malfunction of the pressure boosting device 12 or the like.

The control device 31 is connected to a display device 33 composed of a liquid crystal panel or the like, and displays information related to the operating status of each part of the pressure boosting device 12 (for example, the rotation speed of the hydraulic pump 28). The display device 33 can display the maximum pressure Pmax and the maximum pressure arrival time T, which will be described later. The display device 33 is arranged at an arbitrary position of the bucket 9. The display device 33 may be configured by a tablet PC or the like.

In this embodiment, the pressure boosting cylinder 13 of the pressure booster 12 of the aerial work platform 1, the preload switching valve 17, the relief valve 21, the main pressure switching valve 24, the pilot check valve 27, the hydraulic pump 28 and the control The device 31 is provided on the vehicle 2 of the aerial work platform 1. In the pressure booster 12, the hydraulic hose constituting the supply oil passage 15 is piped to the bucket 9 via the telescopic boom 8. A joint 16 for connecting a hydraulic crimping tool or the like is provided at the tip of the hydraulic hose.

Next, with reference to FIGS. 2 and 4, the operation mode of the pressure booster 12 in the caulking work of the sleeve S for electrical wiring by the hydraulic crimping tool 100 will be described. In the present embodiment, the pressure booster 12 is connected to the hydraulic crimping tool 100 to the joint 16 and the tool operating tool 100c of the hydraulic crimping tool 100 to the control device 31 via the connector 31a. To do.

The hydraulic crimping tool 100 connected to the pressure booster 12 grips and crimps the sleeve S for electrical wiring. The hydraulic crimping tool 100 is configured such that the movable portion 100a moves toward the receiving portion 100b by the hydraulic oil supplied from the pressure boosting device 12. In the hydraulic crimping tool 100, the movable portion 100a is stopped in the stopped state s0 by the operation of the tool operating tool 100c, the movable portion 100a is moved toward the receiving portion 100b, and the sleeve S is moved to the movable portion 100a and the receiving portion 100b. The temporary holding operation s1 to be gripped by the above, the preloading step s2 of the main compression operation in which the movable portion 100a is pressed by a predetermined force to apply a preload to the sleeve S, and the movable portion 100a is pressed by a predetermined force to press the sleeve S. The main pressure step s3 of the main compression operation of caulking and the return operation s4 in which the movable portion 100a is moved away from the receiving portion 100b to release the sleeve S can be performed.

When the operation mode of the hydraulic crimping tool 100 is switched to the stopped state by the operation of the tool operating tool 100c, the control device 31 moves the spool position of the preload switching valve 17 to the II position, and the main pressure switching valve 24 By moving the spool position of No. II to the position II, the hydraulic crimping tool 100 is stopped.

When the operation mode of the hydraulic crimping tool 100 is switched to the temporary holding operation s1 by the operation of the tool operating tool 100c, the control device 31 moves the spool position of the preload switching valve 17 to the I position, and is equal to or less than the relief flow rate. The hydraulic oil controlled by the above is supplied to the booster chamber 13a of the booster cylinder 13 and the hydraulic crimping tool 100. As a result, the hydraulic crimping tool 100 grips the sleeve S.

When the operation mode of the hydraulic crimping tool 100 is switched to the main compression operation by the operation of the tool operating tool 100c, the control device 31 moves the spool position of the preload switching valve 17 to the III position and increases the hydraulic oil. It is supplied to the pressure chamber 13a and the hydraulic crimping tool 100. As a result, the hydraulic crimping tool 100 applies a preload to the sleeve S.

When the detected value of the pressure sensor 14 reaches the preload reference value Pb (see FIG. 5) in the preload step s2 of this compression operation, the control device 31 moves the spool position of the preload switching valve 17 to the II position. The spool position of the main pressure switching valve 24 is moved to the III position. As a result, the movable portion 100a is pressed by the hydraulic oil boosted by the pressure boosting cylinder 13 to crimp the sleeve S.

When the detected value of the pressure sensor 14 reaches the main pressure reference value Pc (see FIG. 5) by operating the tool operating tool 100c, the control device 31 moves the spool position of the main pressure switching valve 24 to the I position. The hydraulic pressure of the hydraulic oil is reduced and the pilot check valve 27 is opened to discharge the hydraulic oil to the hydraulic oil tank 30. As a result, the hydraulic crimping tool 100 releases the sleeve S.

Further, when the flood control switching operation tool 11a of the aerial work platform 1 is operated, the control device 31 moves the spool position of the preload switching valve 17 to the II position regardless of the detected value of the pressure sensor 14. The spool position of the pressure switching valve 24 is moved to the I position. As a result, the hydraulic pressure of the hydraulic oil is reduced, the pilot check valve 27 is opened, and the hydraulic oil is discharged to the hydraulic oil tank 30.

A method of detecting a defect of the pressure booster 12 in the caulking operation by the hydraulic crimping tool 100 will be described with reference to FIGS. 5 to 8. The malfunction of the pressure booster 12 here is not only a minor one generated because the state of the directional control valve, the hydraulic circuit, the hydraulic pump, etc. constituting the pressure booster 12 is not good, but also the directional control valve, the hydraulic circuit, etc. , Those caused by the failure of hydraulic pumps, etc. are also included.

The control device 31 (see FIG. 3) detects a defect by comparing the maximum pressure Pmax detected by the pressure sensor 14 with a predetermined pressure range set in advance. The maximum pressure Pmax detected by the pressure sensor 14 refers to the maximum pressure when the sleeve S is crimped in the main pressure step s3 of the main compression operation. Specifically, for the maximum pressure Pmax, an arbitrary time has elapsed since the detected value of the pressure sensor 14 reached the main pressure reference value Pc and the spool positions of the preload switching valve 17 and the main pressure switching valve 24 were moved. Refers to the later pressure value (see FIG. 5).

As shown in FIG. 6A, the preset predetermined pressure range refers to a pressure value within a range surrounded by an upper limit value Ph and a lower limit value Pl. In the predetermined pressure range, the caulking operation by the hydraulic crimping tool 100 is performed a plurality of times in advance, and the magnitude of the variation in the maximum pressure Pmax value detected by the pressure sensor 14 for each caulking operation (the magnitude of the variation from the target value Pt). It is set from). The target value Pt of the maximum pressure Pmax refers to a value set so that the pressure at which the sleeve S is crimped by the hydraulic crimping tool 100 is an arbitrary value within the specified pressure of the sleeve S. The standard deviation is used to calculate the magnitude of the variation in the value of the maximum pressure Pmax.

In the above configuration, the control device 31 fails in the pressure booster 12 when the maximum pressure Pmax detected by the pressure sensor 14 when the sleeve S is crimped by the hydraulic crimping tool 100 is out of the predetermined pressure range. Detect as. That is, the control device 31 is configured to perform an absolute evaluation for determining the appropriateness of the maximum pressure Pmax for each caulking operation.

Further, the control device 31 detects a defect by comparing the maximum pressure arrival time T from a predetermined timing to reaching the maximum pressure Pmax with a preset predetermined time range. The predetermined timing refers to the timing (switching timing) in which the spool position of the preload switching valve 17 or the main pressure switching valve 24 constituting the pressure boosting device 12 is moved. Specifically, when the operation mode of the hydraulic crimping tool 100 is switched to the main compression operation by the operation of the tool operating tool 100c, the detection value of the pressure sensor 14 is the preload reference value in the preload step s2 of the main compression operation. When it reaches Pb, it means that the detected value of the pressure sensor 14 reaches the main pressure reference value Pc by operating the tool operating tool 100c (see FIG. 5).

As shown in FIG. 6B, the preset predetermined time range refers to the time within the range surrounded by the upper limit value Th and the lower limit value Tl. The predetermined time range is set from the magnitude of the variation in the value of the maximum pressure arrival time T for each caulking operation (the magnitude of the variation from the target value Tt) by performing the caulking operation with the hydraulic crimping tool 100 a plurality of times in advance. To. The target value Tt of the maximum pressure arrival time T refers to a reference time until the maximum pressure Pmax is reached when the maximum pressure Pmax is set to the target value Pt. The standard deviation is used to calculate the magnitude of the variation in the value of the maximum pressure arrival time T.

In the above configuration, the control device 31 detects that the maximum pressure arrival time T in the crimping operation by the hydraulic crimping tool 100 is out of the predetermined time range as a defect of the pressure booster 12. That is, the control device 31 is configured to perform an absolute evaluation for determining the appropriateness of the maximum pressure arrival time T for each caulking operation.

The control device 31 is configured to be able to determine whether the maximum pressure Pmax and the maximum pressure arrival time T are within a predetermined appropriate range, respectively, and the maximum pressure Pmax is within a predetermined pressure range, and the maximum pressure arrival time T is provided. Is within the predetermined time range (see FIG. 6C), the directional control valve, the hydraulic circuit, the hydraulic pump, etc. constituting the pressure booster 12 are not defective and are appropriate. It is determined that the vehicle is driven in the state.

A defect detection control of the pressure boosting device 12 by the control device 31 will be described with reference to FIGS. 7 and 8.

In step S110, the control device 31 determines whether or not the operation mode of the hydraulic crimping tool 100 is switched to the temporary holding operation s1 by the operation of the tool operating tool 100c. When the temporary holding operation is switched to s1, the process proceeds to step S120.

In step S120, the control device 31 moves the spool position of the preload switching valve 17 to the I position. The hydraulic crimping tool 100 grips the sleeve S.

In step S130, the control device 31 determines whether or not the operation mode of the hydraulic crimping tool 100 has been switched to the main compression operation by operating the tool operating tool 100c. When the operation is switched to this compression operation, the process proceeds to step 140.

In step S140, the control device 31 moves the spool position of the preload switching valve 17 to the III position. In the hydraulic crimping tool 100, the movable portion 100a is pressed by a predetermined force by the hydraulic oil of the preload that has not been boosted to apply the preload to the sleeve S, and the process proceeds to step S150.

In step S150, the control device 31 determines whether or not the detected value of the pressure sensor 14 has reached the preload reference value Pb. If it is determined in step S150 that the detected value of the pressure sensor 14 has reached the preload reference value Pb, the process proceeds to step S160.

In step S160, the control device 31 moves the spool position of the preload switching valve 17 to the II position and the spool position of the main pressure switching valve 24 to the III position. In the hydraulic crimping tool 100, as the main pressure step s3 of the main compression operation, the movable portion 100a is pressed by the hydraulic oil boosted by the pressure boosting cylinder 13 with a predetermined force to crimp the sleeve S, and the process proceeds to step S170. ..

In step S170, the control device 31 determines whether or not the detected value of the pressure sensor 14 has reached the main pressure reference value Pc. If it is determined in step S170 that the detected value of the pressure sensor 14 has reached the main pressure reference value Pc, the process proceeds to step S180.

In step S180, the control device 31 moves the spool position of the preload switching valve 17 to the II position and the spool position of the main pressure switching valve 24 to the I position. In the hydraulic crimping tool 100, the movable portion 100a is moved in a direction away from the receiving portion 100b to release the sleeve S from the movable portion 100a and the receiving portion 100b, and the process proceeds to step S190.

In step S190, the control device 31 shifts to step S200 when the defect detection control A of the pressure boosting device 12 is started.

In step S200, the control device 31 moves the spool position of the preload switching valve 17 to the II position, moves the spool position of the main pressure switching valve 24 to the I position, and then moves the maximum pressure detected by the pressure sensor 14. Get Pmax. Further, the time from when the detected value of the pressure sensor 14 reaches the main pressure reference value Pc to when the maximum pressure Pmax is reached (maximum pressure reaching time T3) is acquired, and the process proceeds to step S210.

In step S210, the control device 31 determines whether or not the maximum pressure Pmax detected by the pressure sensor 14 is within a predetermined pressure range. When the detected maximum pressure Pmax is within a predetermined pressure range, the process proceeds to step S220. If the detected maximum pressure Pmax is out of the predetermined pressure range, the process proceeds to step S230.

In step S220, the control device 31 determines whether or not the maximum pressure arrival time T3 (see FIG. 5) is within a predetermined time range. When the detected maximum pressure reaching time T3 is within a predetermined time range, the defect detection control A ends, and the process proceeds to step S240. If the detected maximum pressure arrival time T3 is out of the predetermined time range, the process proceeds to step S230.

In step S230, the control device 31 detects as a defect of the pressure boosting device 12. The control device 31 uses the alarm device 32 to notify the operator as a malfunction of the pressure boosting device 12. When the control device 31 detects a defect in the pressure boosting device 12, the defect detection control A ends, and the process proceeds to step S240.

In step S240, the control device 31 determines whether or not a defect of the pressure booster 12 has been detected in the defect detection control A. If a defect is detected, the process proceeds to step S250. If no defect is detected, the process proceeds to step S110.

In step S250, the control device 31 fixes the spool position of the preload switching valve 17 to the II position, fixes the spool position of the main pressure switching valve 24 to the II position, and ends the process.

As described above, by determining whether the maximum pressure Pmax detected by the pressure sensor 14 during the caulking operation is within a predetermined pressure range, it is possible to detect a defect in the pressure booster 12. By detecting a defect in the pressure booster 12 and notifying the operator, the operator can know the defect in the pressure booster 12 during the caulking operation. In addition, the operator can recognize that the caulking work has been performed due to inappropriate pressure.

Similarly, by determining whether the detected maximum pressure arrival time T3 is within a predetermined time range, a defect of the pressure booster 12 can be detected. By detecting a defect in the pressure booster 12 and notifying the operator, the operator can know the defect in the pressure booster 12 during the caulking operation.

In the present embodiment, the time from when the predetermined timing reaches the maximum pressure Pmax is the time from when the detected value of the pressure sensor 14 reaches the main pressure reference value Pc to when the maximum pressure Pmax is reached (maximum pressure reached). The time is T3), but the time is not limited to this. For example, the time from when the operation mode of the hydraulic crimping tool 100 is switched to the main compression operation until the maximum pressure Pmax is reached (maximum pressure arrival time T1) may be set, or the operation of the tool operating tool 100c may be used. In the preload step s2 of the compression operation, the time from when the detected value of the pressure sensor 14 reaches the preload reference value Pb to when the maximum pressure Pmax is reached (maximum pressure arrival time T2) may be set (see FIG. 5).

Further, the time (maximum pressure arrival time T1, T2, T3) until the maximum pressure Pmax is reached from a plurality of predetermined timings is detected, and the respective maximum pressure arrival times T1, T2, T3 are set for each. It may be configured to determine whether or not it is within a predetermined time range. In this way, by configuring the configuration to determine whether the plurality of maximum pressure arrival times T1, T2, and T3 are within the respective predetermined time ranges, it is easy to determine the defective portion such as the failure of the pressure booster 12. Therefore, maintainability is improved. In the above configuration, when setting a predetermined time range, the standard deviation is used as an index indicating the magnitude of variation of each data, but the present invention is not limited to this.

In the following, a control device configured to perform relative evaluation for determining the appropriateness of each maximum pressure Pmax and each maximum pressure arrival time T detected for each operation (caulking operation) by the hydraulic crimping tool 100. 31 will be described. When the control device 31 is switched to a state in which the hydraulic oil increased in pressure can be supplied to the hydraulic crimping tool 100 by the hydraulic switching operating tool 11a, the maximum pressures Pmax detected for each subsequent operation and the maximum pressures are reached. It is configured to determine the appropriateness of each time T.

A second embodiment of a method for detecting a defect in the pressure boosting device 12 will be described with reference to FIG. The malfunction of the pressure booster 12 here is not only a minor one generated because the state of the directional control valve, the hydraulic circuit, the hydraulic pump, etc. constituting the pressure booster 12 is not good, but also the directional control valve, the hydraulic circuit, etc. , Those caused by the failure of hydraulic pumps, etc. are also included.

As shown in FIG. 9A, the control device 31 stores each maximum pressure Pmax detected by the pressure sensor 14 each time the caulking operation is performed in the caulking operation performed a plurality of times. Then, the control device 31 calculates the pressure difference Na between the maximum value and the minimum value of the stored maximum pressure Pmax, compares the pressure difference Na with the preset pressure threshold value, and detects a defect. .. An arbitrary value is set as the pressure threshold value set in advance. For example, it is set based on the specified pressure range of the sleeve S.

In the above configuration, the control device 31 increases when the pressure difference Na between the maximum value and the minimum value is larger than the preset pressure threshold value among the plurality of maximum pressures Pmax stored for each caulking operation. It is detected as a defect of the pressure device 12. That is, the control device 31 is configured to perform a relative evaluation for determining the appropriateness of each maximum pressure Pmax detected for each caulking operation.

As shown in FIG. 9B, the control device 31 stores each maximum pressure arrival time T detected each time the caulking operation is performed in the caulking operation performed a plurality of times. Then, the control device 31 calculates the time difference Nb between the longest value and the shortest value in the stored maximum pressure arrival time T, compares the time difference Nb with the preset time threshold value, and detects a defect. .. An arbitrary value is set as the preset time threshold value. For example, it is set based on the time estimated from the supply pressure of the hydraulic pump and the length of the passage of the supplied hydraulic oil.

In the above configuration, when the time difference Nb between the longest value and the shortest value is larger than the preset time threshold value among the plurality of maximum pressure arrival times T stored for each caulking operation, the control device 31 is used. It is detected as a defect of the pressure booster 12. That is, the control device 31 is configured to perform a relative evaluation for determining the appropriateness of each maximum pressure arrival time T detected for each caulking operation.

Further, when the hydraulic pressure switching operation tool 11a switches to a state in which the increased hydraulic oil can be supplied to the hydraulic crimping tool 100, the maximum pressures Pmax detected for each operation and the maximum pressure arrival times T are appropriate. It is configured to determine each sex, but is not limited to this. For example, when the control device 31 is turned on, the appropriateness of each maximum pressure Pmax detected for each operation and each maximum pressure arrival time T may be determined. Further, the maximum pressure Pmax and the maximum pressure arrival time T accumulated for determining the appropriateness of each maximum pressure Pmax and each maximum pressure arrival time T are determined every predetermined number of times, every predetermined time, or at a predetermined value. It may be reset every number of days (for example, one day).

A defect detection control of the pressure boosting device 12 by the control device 31 will be described with reference to FIGS. 10 to 12. In the description of FIG. 10, since steps S110 to S180 are the same steps as those of the embodiment in FIG. 7, the description will be given from step S180.

In step S180, the control device 31 moves the spool position of the preload switching valve 17 to the II position and the spool position of the main pressure switching valve 24 to the I position. In the hydraulic crimping tool 100, the movable portion 100a is moved in a direction away from the receiving portion 100b to release the sleeve S from the movable portion 100a and the receiving portion 100b, and the process proceeds to step S290.

In step S290, the control device 31 shifts to step S300 when the defect detection control B based on the maximum pressure Pmax of the pressure boosting device 12 is started.

In step S300, the control device 31 moves the spool position of the preload switching valve 17 to the II position, moves the spool position of the main pressure switching valve 24 to the I position, and then moves the maximum pressure detected by the pressure sensor 14. Pmax is acquired and the process proceeds to step S310.

In step S310, the control device 31 determines whether or not the detected maximum pressure Pmax (detected value) is larger than the maximum value in the stored maximum pressure Pmax. If the detected value is larger than the maximum value, the process proceeds to step S320. If the detected value is not larger than the maximum value, the process proceeds to step S350.

In step S320, the control device 31 sets the detected value as the maximum value and shifts to step S330.

In step S330, the control device 31 determines whether or not the pressure difference Na between the detected value and the minimum value in the stored maximum pressure Pmax is larger than the preset pressure threshold value. When the pressure difference Na between the maximum value and the minimum value is larger than the pressure threshold value, the process proceeds to step S340. When the pressure difference Na between the maximum value and the minimum value is not larger than the pressure threshold value, the defect detection control B based on the maximum pressure Pmax ends, and the process proceeds to step S390.

In step S340, since the pressure difference Na between the maximum value and the minimum value is larger than the pressure threshold value, the control device 31 detects it as a defect of the pressure boosting device 12. The control device 31 uses the alarm device 32 to notify the operator as a malfunction of the pressure boosting device 12. When the control device 31 detects a defect in the pressure boosting device 12, the defect detection control B based on the maximum pressure Pmax ends, and the process proceeds to step S390.

In step S350, the control device 31 determines whether or not the detected maximum pressure Pmax (detected value) is smaller than the minimum value in the stored maximum pressure Pmax. If the detected value is smaller than the minimum value, the process proceeds to step S360. If the detected value is not smaller than the minimum value, the defect detection control B based on the maximum pressure Pmax ends, and the process proceeds to step S390.

In step S360, the control device 31 sets the detected value as the minimum value and shifts to step S370.

In step S370, the control device 31 determines whether or not the pressure difference Na between the detected value and the maximum value in the stored maximum pressure Pmax is larger than the preset pressure threshold value. When the pressure difference Na between the maximum value and the minimum value is larger than the pressure threshold value, the process proceeds to step S340. When the pressure difference Na between the maximum value and the minimum value is not larger than the pressure threshold value, the defect detection control B based on the maximum pressure Pmax ends, and the process proceeds to step S390.

In step S390, the control device 31 shifts to step S400 when the failure determination control C based on the maximum pressure arrival time T of the pressure boosting device 12 is started.

In step S400, the control device 31 determines whether or not a defect has been detected in the defect detection control B based on the maximum pressure Pmax. When a defect is detected, the defect detection control C based on the maximum pressure arrival time T ends, and the process proceeds to step S490. If no defect is detected, the process proceeds to step S410.

In step S410, the control device 31 moves the spool position of the preload switching valve 17 to the II position, moves the spool position of the main pressure switching valve 24 to the I position, and then sets the detected maximum pressure arrival time T. Acquire and move to step S420.

In step S420, the control device 31 determines whether or not the detected maximum pressure arrival time T (detection value) is larger than the longest value in the stored maximum pressure arrival time T. If the detected value is larger than the longest value, the process proceeds to step S430. If the detected value is not larger than the longest value, the process proceeds to step S460.

In step S430, the control device 31 sets the detected value as the longest value and shifts to step S440.

In step S440, the control device 31 determines whether or not the time difference Nb between the detected value and the shortest value in the stored maximum pressure arrival time T is larger than the preset time threshold value. When the time difference Nb between the longest value and the shortest value is larger than the time threshold value, the process proceeds to step S450. When the time difference Nb between the longest value and the shortest value is not larger than the time threshold value, the defect detection control C based on the maximum pressure arrival time T ends, and the process proceeds to step S490.

In step S450, since the time difference Nb between the longest value and the shortest value is larger than the time threshold value, the control device 31 detects it as a defect of the pressure booster 12. The control device 31 uses the alarm device 32 to notify the operator as a malfunction of the pressure boosting device 12. When the control device 31 detects a defect in the pressure boosting device 12, the defect detection control C based on the maximum pressure arrival time T ends, and the process proceeds to step S490.

In step S460, the control device 31 determines whether or not the detected value is smaller than the shortest value in the stored maximum pressure arrival time T. If the detected value is smaller than the shortest value, the process proceeds to step S470. If the detected value is not smaller than the shortest value, the time difference Nb between the longest value and the shortest value in this caulking operation is not larger than the time threshold value, so that the defect detection control C based on the maximum pressure arrival time T ends, and the step Move to S490.

In step S470, the control device 31 sets the detected value as the shortest value and shifts to step S480.

In step S480, the control device 31 determines whether or not the time difference Nb between the detected value and the longest value in the stored maximum pressure arrival time T is larger than the preset time threshold value. When the time difference Nb between the longest value and the shortest value is larger than the time threshold value, the process proceeds to step S450. When the time difference Nb between the longest value and the shortest value is not larger than outside the time threshold value, the defect detection control C based on the maximum pressure arrival time T ends, and the process proceeds to step S490.

In step S490, the control device 31 determines whether or not a defect has been detected in the defect detection control B based on the maximum pressure Pmax or the defect detection control C based on the maximum pressure arrival time T. If a defect is detected, the process proceeds to step S500. If no defect is detected, the process proceeds to step S110.

In step S500, the control device 31 fixes the spool position of the preload switching valve 17 to the II position, fixes the spool position of the main pressure switching valve 24 to the II position, and ends the process.

As described above, the control device 31 is configured to perform a relative evaluation for determining the appropriateness of each maximum pressure Pmax, so that it is possible to detect a defect in the pressure booster 12 and notify the operator. it can. Further, by comparing the values of the maximum pressures Pmax, it is possible to detect a defect before the pressure booster 12 fails. In addition, the operator can recognize that the caulking work has been performed due to inappropriate pressure.

Similarly, the control device 31 is configured to perform a relative evaluation for determining the appropriateness of each maximum pressure arrival time T, thereby detecting a defect in the pressure boosting device 12 and notifying the operator. it can. Further, by comparing the values of the maximum pressure arrival times T, it is possible to detect a defect before the pressure booster 12 fails.

In the above configuration, the control device 31 performs an absolute evaluation for determining the appropriateness of the maximum pressure Pmax and the maximum pressure arrival time T for each caulking operation, and each maximum pressure Pmax detected for each caulking operation and the maximum. Relative evaluation for determining the appropriateness of each pressure arrival time T may be performed in combination. In this case, if a defect is detected in either the absolute evaluation or the relative evaluation, the operator is notified as a defect of the pressure booster 12. As described above, by using the absolute evaluation and the relative evaluation together, the accuracy of detecting the defect of the pressure booster 12 can be improved.

1 High-place work vehicle 13 Pressure boosting cylinder 13a Pressure boosting chamber 13b Rod side oil chamber 13c Head side oil chamber 14 Pressure sensor 15 Supply oil passage 17 Preload switching valve 24 Main pressure switching valve 25 Pressure reducing oil passage 26 Pressure boosting oil passage 31 Control device Pmax Maximum pressure T Maximum pressure arrival time Na Pressure difference Nb Time difference

Claims (4)

A pressure booster for aerial work platforms that supplies hydraulic oil boosted by a pressure boost cylinder to flood control tools.
A supply oil passage connecting the pressure boosting chamber of the pressure boosting cylinder and the hydraulic tool, and
A booster oil passage that guides hydraulic oil to the oil chamber on the head side of the booster cylinder, and
A decompression oil passage that guides hydraulic oil to the rod-side oil chamber of the booster cylinder, and
An electromagnetic switching valve for preload connected to the supply oil passage and
A state in which hydraulic oil is supplied to the head side oil chamber of the pressure boosting cylinder through the pressure boosting cylinder connected to the pressure boosting cylinder, and hydraulic oil is supplied to the rod side oil chamber of the pressure booster cylinder through the pressure reducing oil passage. An electromagnetic switching valve for main pressure that can be switched between the supply state and
A pressure detecting means for detecting the pressure in the pressure boosting chamber is provided.
The maximum pressure detected by the hydraulic tool for each of a plurality of operations in the operation of performing the main compression operation is memorized, and the pressure difference between the maximum value and the minimum value of the memorized maximum pressures for each operation is larger than the pressure threshold. When it is large , or for each of the operations, the maximum pressure arrival time from the switching timing of the electromagnetic switching valve for preload or the electromagnetic switching valve for main pressure to reaching each maximum pressure is memorized and the stored maximum. A pressure booster for aerial work platforms that detects as a defect when the time difference between the longest and shortest pressure arrival times is larger than the time threshold. The pressure booster for aerial work platforms according to claim 1, wherein when the maximum pressure detected by the pressure detecting means is out of a predetermined pressure range, it is detected as a defect. Claim 1 or claim 1 or the above, when the maximum pressure arrival time from the switching timing of the preload electromagnetic switching valve or the main pressure electromagnetic switching valve to reaching the maximum pressure is out of the predetermined time range, it is detected as a defect. The pressure booster for aerial work platforms according to claim 2. The aerial work platform according to claim 3, wherein each maximum pressure arrival time from the plurality of switching timings to the arrival of the maximum pressure is detected as a defect when the time is out of the set predetermined time range. Pressure booster.

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