JP6719417B2 - Operating device and electric chain block - Google Patents

Description

The present invention relates to an operating device and an electric chain block.

For example, an electric chain block includes an operating device for operating the drive of a motor when moving a load up and down. Such an operating device is generally configured to hang down from the main body of the electric chain block separately from the load chain and the lower hook. However, there is an operating device that is connected to a load chain or a lower hook. An example of such an operating device is a cylindrical (cylinder-shaped) operating device that is gripped and operated by an operator, and a load chain and a lower hook are integrally attached to the operating device so that the operator can move up and down with a load. It is like this. An electric chain block and a rope hoist equipped with such an operating device are called a cylinder type hoist. Further, in the following description, the operating device provided in the cylinder type electric chain block is referred to as a cylinder operating device.

Patent Document 1 discloses an example of such a cylinder operating device. In the configuration of Patent Document 1, when the operation grip is moved up and down, the detection plate also moves up and down, but the detection plate is provided with a plurality of respective slits such as an upper slit and a lower slit. Moreover, each photoelectric slit such as an upper photoelectric switch, a lower photoelectric switch, and a middle photoelectric switch is provided so as to sandwich the detection plate.

In the configuration disclosed in Patent Document 1, when the detection plate slides, the signal level output by each photoelectric switch changes depending on whether or not the photoelectric switch approaches the slit. Therefore, the operation of the operating grip (whether it is an up/down operation or a down operation) is determined according to the signal levels of the three photoelectric switches described above, and the drive direction of the motor and the control of the drive speed by counting the ON-OFF signals are determined. It is configured to be able to.

JP, 2008-74555, A

By the way, in the configuration disclosed in Patent Document 1, the photoelectric switch is arranged inside the cylindrical cylinder. However, the cylinder itself does not have a waterproof structure such as sealing the gap including the upper end side and the lower end side. Therefore, there is a possibility that the liquid enters through the gap as described above, which may adversely affect the photoelectric switch, the substrate on which the photoelectric switch is mounted, and the like. The liquid may be invaded, for example, when rainwater is used when the cylinder type electric chain block is used outdoors or when oil mist is used when the cylinder type electric chain block is used in a factory.

In addition, the configuration disclosed in Patent Document 1 has a problem that the accuracy of detecting the slide amount of the operation grip is not good. That is, the operation grip and the detection plate are attracted by the magnetic force, but the direction in which the magnetic force acts and the sliding direction of the operation grip are orthogonal to each other. Therefore, since the slide of the detection plate does not directly correspond to the slide of the operation grip, the detection accuracy is not good. Further, as described above, for example, when the cylinder type electric chain block is used for a long period of time in an environment where oil mist enters, detection accuracy deteriorates due to adhesion of oil mist to the photoelectric switch. There is also the problem of being lost.

The present invention has been made in view of the above circumstances, and an object thereof is to provide an operating device and an electric chain block that have high airtightness and can improve detection accuracy.

In order to solve the above problems, according to a first aspect of the present invention, there is provided a manipulating device for manipulating a drive of a motor for hoisting and lowering a load chain, the mandrel extending vertically. , A tubular body that covers the core rod and has a compartment that has airtightness inside, and is slidable in the axial direction with respect to the tubular body and operable from the entire circumferential direction on the outer peripheral side of the tubular body A slide member, and an operation switch mechanism for controlling the drive of the motor according to the amount of slide of the slide member. Inside the tubular body , the operation member is separated from the compartment on the lower side of the compartment. An inner cylinder chamber is provided, and the operation switch mechanism includes a moving member that interlocks with the slide of the slide member, a sensor that is housed in the compartment and that detects the moving amount of the moving member, and a detection signal of the sensor. Circuit board for controlling the drive of the motor, a slide ring that slides along the core rod inside the inner cylinder chamber as the slide member slides, and a slide ring that is attached to the slide ring and has an upper side through an insertion hole. And a slide bar corresponding to the moving member, the amount of slide being detected by the sensor, and the slide bar corresponding to the moving member .

Further, according to another aspect of the present invention, in the above-mentioned invention, it is preferable that the slide ring is elastically supported by an elastic member, and the slide ring, the slide bar, and the slide member return to the initial position when not operated. ..

Another aspect of the present invention is, in the above-mentioned invention, the tubular body is provided with an electrical equipment storage portion having a compartment and a distance from the core rod to the outer peripheral surface, the electrical equipment storage portion being provided below the electrical equipment storage portion. Is provided shorter than the electrical component storage portion, and a slide guide portion on which the slide member slides along the outer peripheral surface is provided, and a slide guide portion is provided below the slide guide portion, and the distance from the core rod to the outer peripheral surface is the slide guide. And a lower cover portion that is provided longer than the portion.

Further, according to another aspect of the present invention, in the above-mentioned invention, a lower hook for loading a load is detachably attached to the core rod through the attachment/detachment mechanism, and the attachment/detachment mechanism allows the lower hook to rotate. Is preferred.

Further, in another aspect of the present invention, in the above-described invention, it is preferable that the sensor is an angle sensor that includes a rotating shaft that rotates according to the slide amount of the slide bar and that detects the rotating amount of the rotating shaft. ..

Further, according to another aspect of the present invention, in the above-mentioned invention, it is preferable that the sensor is a magnetic sensor that detects a change in a magnetic field corresponding to a slide amount of the slide bar.

According to a second aspect of the present invention , there is provided a manipulating device for manipulating the drive of a motor for hoisting and lowering a load chain, the mandrel extending vertically and covering the mandrel. A tubular body provided with a compartment having airtightness inside, and a slide member slidable in the axial direction with respect to the tubular body and operable from the entire outer peripheral side of the tubular body, An operation switch mechanism for controlling the drive of the motor according to the slide amount of the slide member, the operation switch mechanism including a moving member that interlocks with the slide of the slide member and a moving member that is housed in the compartment and that moves. A tubular body is provided with a sensor that detects the amount of movement and a circuit board that controls the drive of the motor based on the detection signal of the sensor. A cylinder chamber is provided, the operation switch mechanism slides along the core rod inside the inner cylinder chamber as the slide member slides, and includes a slide ring corresponding to the moving member. is a non-contact short-range sensor for measuring a moving distance of the ring, the operating device is provided, characterized in that.

According to a third aspect of the present invention, the load chain is provided with the operating device according to each of the above inventions, and is connected to the upper end side of the operating device, and the load chain is connected to the lower end side of the operating device. There is provided an electric chain block comprising: a lower hook for suspending a load chain; and a motor for hoisting and lowering a load chain.

According to the present invention, it is possible to provide an operating device and an electric chain block that are highly airtight, have a simple configuration, and can improve detection accuracy.

It is a side view showing the whole electric chain block composition concerning one embodiment of the present invention. FIG. 2 is a side sectional view showing a configuration of a cylinder operating device in the electric chain block shown in FIG. 1. FIG. 2 is a plan cross-sectional view showing a configuration in the vicinity of an electric component storage portion of a cylinder operating device in the electric chain block shown in FIG. 1. FIG. 2 is a side sectional view showing a rack gear portion existing above the slide bar in the electric chain block shown in FIG. 1 and showing a pinion gear meshing with the rack gear portion. FIG. 13 is a side sectional view showing an operation switch mechanism including a rotation arm type angle sensor according to the second configuration example of the present embodiment. FIG. 13 is a plan cross-sectional view showing a configuration in the vicinity of an electrical component storage portion of the cylinder operating device according to the third configuration example of the present embodiment. It is a front sectional view showing an operation switch mechanism provided with a magnetic sensor concerning a 3rd example of composition of this embodiment, and is a figure showing the state where the magnetic sensor vicinity was cut. It is a partial front sectional view showing a switch mechanism provided with a non-contact distance measuring sensor according to a modification of the present invention.

Hereinafter, a cylinder operating device 100 as an operating device and an electric chain block 10 including the cylinder operating device 100 according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the Z direction refers to the direction in which the load chain C1 and the rotary hook 100 are suspended, the Z1 side refers to the upper side, and the Z2 side refers to the opposite lower side. Further, the Y direction refers to the direction connecting the first partitioned chamber 142 and the second partitioned chamber 143 in FIG. 3, the Y1 side refers to the second partitioned chamber 143 side as viewed from the first partitioned chamber 142, and the Y2 side The side refers to the first compartment 142 side when viewed from the opposite second compartment 143 side.

<Overall structure of electric chain block>
FIG. 1 is a side view showing the overall configuration of the electric chain block 10. The electric chain block 10 includes an upper hook 20, a chain block body 30, and a load chain C1. The chain block body 30 includes a motor 40, and by driving the motor 40, the load chain C1 can be hoisted and unwound. The electric chain block 10 also includes a bucket 50 for housing the load chain C1.

A rotary hook 60 is provided on the lower side (Z2 side) of the cylinder device 100 (described later). The rotating hook 60 includes an attaching/detaching metal member mechanism 70 and a lower hook 80, and the lower hook 80 is rotatably supported by the attaching/detaching metal member mechanism 70. The lower hook 80 is provided in a hook shape so that a load can be applied thereto, and a hook latch 82 for preventing the load from coming off is attached to the hook-shaped opening 81. The hook latch 82 is provided so as to be openable and closable around the pivot shaft 83 as a fulcrum, but is normally urged in the closing direction by a spring (not shown).

The attachment/detachment metal fitting mechanism 70 is a portion that rotatably supports the lower hook 80 and also detachably supports the lower hook 80. The attachment/detachment metal fitting mechanism 70 is provided with a connecting portion 71, and a male screw portion 72 is provided on the outer periphery of the connecting portion 71. The male screw portion 72 is a portion screwed into the female screw portion 133 of the connecting fitting 130. The attaching/detaching metal member mechanism 70 is connected to the connecting metal member 130 by interposing a predetermined retaining mechanism together with the screwing.

<Details of internal configuration of cylinder operating device>
Next, details of the configuration of the cylinder operating device 100 will be described. FIG. 2 is a side sectional view showing the configuration of the cylinder operating device 100. FIG. 3 is a plan cross-sectional view showing a configuration of the cylinder operating device 100 in the vicinity of the electrical component storage portion. The cylinder operating device 100 is for operating the drive of the motor 40, and is electrically connected to the chain block body 30 via a cable 90 (curl cord). Further, in the configuration shown in FIG. 2, the upper end side (Z1 side) of the cylinder operating device 100 is covered with a bellows portion 91 for dust prevention.

As shown in FIGS. 2 and 3, the cylinder operating device 100 includes a core rod 110, an upper bracket 120, a connecting fitting 130, a tubular body 140, and an operation switch mechanism 150. The core rod 110 is a metal rod-shaped portion, and is a portion that supports the load of a load suspended by the lower hook 80. The upper end side of the core rod 110 is connected to the upper bracket 120. The upper bracket 120 is a portion that fixes the upper end of the core rod 110 and is connected to the lower end side of the load chain C1.

The lower end side of the core rod 110 is connected to the connecting fitting 130. The connecting fitting 130 is provided with a connecting portion 131, and is connected to the lower end side of the core rod 110 via the connecting portion 131. Further, a tubular joint portion 132 is integrally provided on the connecting portion 131 of the connecting fitting 130. A female screw portion 133 is formed on the inner cylinder side of the joint portion 132, and the male screw portion 72 is screwed into the female screw portion 133.

Further, the tubular body 140 is attached to the outside of the core rod 110, the upper bracket 120, and the connecting fitting 130. As shown in FIG. 3, the tubular body 140 is configured by combining two resin molded bodies 140M1 and 140M2 formed of resin, for example. In the configuration shown in FIG. 3, the vicinity of the electrical component storage portion 141 of the tubular body 140 is provided so that the cross-sectional shape cut along a plane perpendicular to the hanging direction (Z direction) is rectangular. However, this cross-sectional shape may be provided in a circular shape, or may be provided in other shapes. The cross-sectional shape of the vicinity of the slide guide portion 147 and the lower cover portion 149 other than the electrical component storage portion 141 is provided to be circular.

The tubular body 140 includes an electrical component storage portion 141, a slide guide portion 147, and a lower cover portion 149 from the upper side (Z1 side) toward the lower side (Z2 side). The electrical component storage portion 141 is a portion that stores electrical components in its internal space. Therefore, the electrical component storage portion 141 is provided so as to be airtight to the outside. However, any part of the electrical component storage portion 141 may be configured to communicate with the internal space of the slide guide portion 147 located on the lower side (Z2 side) thereof.

Further, the electrical component storage portion 141 is provided so that the internal space is larger than that of the slide guide portion 147. In the internal space of the electrical component storage portion 141, the first compartment 142 and the second compartment are provided. The chamber 143, the core rod mounting chamber 144, and the sliding chamber 145 are partitioned at least. Of these, the first partitioned chamber 142 and the sliding chamber 145 correspond to the partitioned chambers, but the second partitioned chamber 143 and the core rod mounting chamber 144 may also correspond to the partitioned chambers.

Of these chambers 142 to 145, the first compartment 142 is an internal space of the tubular body 140 provided on one side (Y1 side) in the width direction (Y direction). A circuit board 180 that constitutes the operation switch mechanism 150 is arranged in the first compartment 142. An angle sensor 173 is also arranged in the first compartment 142, and the angle sensor 173 is mounted on the circuit board 180. The angle sensor 173 will be described later.

Further, the second compartment 143 is an internal space of the tubular body 140 provided on the other side (Y2 side) in the width direction (Y direction). In this second compartment 143, an emergency stop switch 200 for emergency stop of driving of the motor 40 projects into the space. The emergency stop switch 200 is electrically connected to the circuit board 180 via wiring. Therefore, the first compartment 142 and the second compartment 143 are spatially connected at a predetermined site such as the upper side or the lower side.

Further, the core rod mounting chamber 144 is a portion where the core rod 110 is mounted in the central portion of the second partitioned chamber 143. The sliding chamber 145 is a space located between the first partitioned chamber 142 and the second partitioned chamber 143. The sliding chamber 145 accommodates the slide bar 172 that constitutes the operation switch mechanism 150, and This is the part that guides the slide. In the configuration shown in FIG. 3, the sliding chamber 145 and the first partitioned chamber 142 are provided so as to communicate with each other through the communication hole 146. Further, as shown in FIG. 2, the sliding chamber 145 is provided so as to communicate with the inner cylinder chamber 148 located on the lower side thereof through the insertion hole 145a, and the slide bar 172 is provided in the insertion hole 145a. It is provided to be inserted. It is preferable that a packing or the like be provided on the inner wall side of the insertion hole 145a so that the sliding of the slide bar 172 can be guided in an airtight state.

The slide guide portion 147 is a portion located below the electrical component storage portion 141. On the outer peripheral side of the slide guide portion 147, a slide member 160 (described later) can be guided to slide. An inner cylinder chamber 148 is provided inside the slide guide portion 147. A slide ring 171 is accommodated in the inner cylinder chamber 148 so as to be slidable along the core rod 110. In addition, the inner cylinder chamber 148 also houses an upper spring 174 and a lower spring 175 for applying a biasing force to the slide ring 171.

The lower cover portion 149 is a portion that covers the coupling fitting 130 on the lower side of the slide guide portion 147.

<About operation switch mechanism>
Next, the operation switch mechanism 150 will be described. The operation switch mechanism 150 has a slide member 160, a slide amount detection mechanism 170, and a circuit board 180 as main components. Of these, the slide member 160 is provided on the outer peripheral side of the slide guide portion 147 of the tubular body 140. The slide member 160 is a member that an operator holds with his/her hand. The slide member 160 is provided with an appropriate uneven shape so as not to slip when the operator grips it.

Further, the slide amount detection mechanism 170 includes a slide ring 171, a slide bar 172, an upper spring 174, a lower spring 175, and an angle sensor 173. At least one of the upper spring 174 and the lower spring 175 corresponds to an elastic member. Of these, the slide ring 171 is provided on the outer peripheral side of the core rod 110 and is slidable along the core rod 110. Further, the slide ring 171 is provided so as to slide integrally with the slide member 160. Therefore, the slide member 160 and the slide ring 171 are connected by a connecting member such as a connecting pin 176. The slide guide portion 147 is also provided with a long hole 147a for inserting the connecting pin 176.

Further, as shown in FIG. 2, the slide bar 172 is a member that projects further upward from the upper surface side (surface on the Z1 side) of the slide ring 171. The slide bar 172 is provided so as to extend from the inner cylindrical chamber 148 to the upper (Z1 side) sliding chamber 145 by being inserted through the insertion hole 145a described above. The slide bar 172 corresponds to the moving member.

FIG. 4 is a side sectional view showing a rack gear portion 172a existing above the slide bar 172 and a pinion gear 173b meshing with the rack gear portion 172a. As shown in FIG. 4, a rack gear portion 172a is provided above the slide bar 172. The rack gear portion 172a meshes with the pinion gear 173b attached to the rotation shaft 173a of the angle sensor 173.

The angle sensor 173 corresponds to a sensor. The angle sensor 173 can detect the rotation angle based on the rotation amount of the rotation shaft 173a. Therefore, when the slide bar 172 slides, the rotary shaft 173a is rotated by the meshing of the rack gear portion 172a and the pinion gear 173b. The angle sensor 173 can detect the slide amount of the slide bar 172 (slide member 160) by detecting the rotation amount. Various types of angle sensor 173 can be used. For example, a rotary encoder system, a resolver system, a potentiometer system, etc. may be mentioned, but other types of angle sensors may be used.

The upper spring 174 is a member that is arranged on the upper side (Z1 side) of the slide ring 171 and applies a biasing force to the slide ring 171 toward the lower side (Z2 side). The lower spring 175 is a member that is arranged on the lower side (Z2 side) of the slide ring 171 and applies a biasing force to the slide ring 171 toward the upper side (Z1 side). Therefore, when the operator does not hold and slide the slide member 160, the slide ring 171 is in a neutral position where the upper spring 174 and the lower spring 175 are in balance.

Further, the above-mentioned angle sensor 173 is attached to the circuit board 180. The circuit board 180 sends a drive signal for the motor 40 according to the detection of the angle sensor 173 and a drive signal for stopping the motor 40 according to the operation of the emergency stop switch 200 to the motor 40 side via the cable 90. Send. Specifically, the circuit board 180 drives the motor 40 so as to lower the lower hook 80 when the slide member 160 moves downward from the neutral position. Further, the circuit board 180 drives the motor 40 so as to raise the lower hook 80 when the slide member 160 moves upward from the neutral position.

In the driving of the motor 40, the speed of the motor 40 is changed stepwise in accordance with the detection of the slide amount by the angle sensor 173, for example, in two steps or three steps on the ascending side and the descending side, respectively. Alternatively, the speed of the motor 40 may be linearly (steplessly) changed according to the detection of the slide amount.

<Regarding Second Configuration Example of Operation Switch Mechanism>
In the configurations shown in FIGS. 2 and 3 described above, the operation switch mechanism 150 uses the rack-and-pinion type angle sensor that rotates the rotating shaft 173a. However, the operation switch mechanism is not limited to such a configuration. For example, the configuration shown in FIG. 5 may be used. FIG. 5 is a side cross-sectional view showing an operation switch mechanism 150B including a rotation arm type angle sensor 173B according to the second configuration example of the present embodiment.

In the configuration shown in FIG. 5, the rotation arm 177B is attached to the rotation shaft 173Ba of the angle sensor 173B. Further, the upper end side of the slide bar 172B is pressed against the rotating arm 177B. In addition, it is preferable that the rotating arm 177B is configured to apply an urging force such that the rotating arm 177B maintains contact with the slide bar 172B by an urging means such as a spring (not shown).

In the above-described configuration, the rotating arm 177B rotates as the slide bar 172B slides. The angle sensor 173B can detect the slide amount of the slide bar 172B (slide member 160) by detecting the rotation amount.

<Regarding Third Configuration Example of Operation Switch Mechanism>
Further, the operation switch mechanism may be configured differently from the above. FIG. 6 is a plan cross-sectional view showing a configuration in the vicinity of the electrical component storage portion 141C of the cylinder operating device 100C according to the third configuration example of the present embodiment. FIG. 7 is a front sectional view showing an operation switch mechanism 150C including a magnetic sensor 178C according to the third configuration example of the present embodiment, and is a view showing a state in which the vicinity of the magnetic sensor 178C is cut. There are various types of magnetic sensors, but the magnetic sensor 178C shown in FIGS. 6 and 7 includes a sensor main body 178C1 and a magnet 178C2. The sensor body 178C1 is attached to, for example, the circuit board 180. Various configurations can be applied to the sensor main body 178C1, such as one provided with a Hall IC, one provided with a magnetic impedance element, and one utilizing a coil.

In the configuration shown in FIGS. 6 and 7, two magnets 178C2 are provided and attached to the slide bar 172C at predetermined intervals in the vertical direction (Z direction). Therefore, it is possible to detect the vertical position (Z direction) of the slide bar 172C with respect to the sensor body 178C1.

<About effect>
The electric chain block 10 configured as described above includes the core rod 110 that extends in the vertical direction (Z direction), and further includes the tubular body 140 that covers the core rod 110. It is provided with compartments such as a first compartment 142 and a sliding chamber 145 that are airtight. Further, a slide member 160 is provided, and the slide member 160 is slidable with respect to the tubular body 140 and can be operated from the entire circumferential direction on the outer peripheral side of the tubular body 140. Furthermore, the operation switch mechanism 150 is provided, and the operation switch mechanism 150 controls the drive of the motor 40 according to the slide amount of the slide member 160. Here, the concept of "according to the slide amount of the slide member 160" includes the case where the drive of the motor 40 is linearly controlled according to the slide amount, and the case where the motor 40 is controlled stepwise with respect to the slide amount. Is included. In addition, an operation as an on/off switch that switches the operation of the motor 40 depending on whether or not a certain amount of slide is performed regardless of the amount of slide is included.

Further, the operation switch mechanism 150 is housed in a compartment such as the first compartment 142 and has sensors such as angle sensors 173, 173B and a magnetic sensor 178C for detecting the movement amount of the slide bar 172 (moving member). A circuit board 180 for controlling the drive of the motor 40 based on the detection signal of the sensor is also provided.

Therefore, the sensor (angle sensor 173, 173B, magnetic sensor 178C) and the circuit board 180 are housed in the highly airtight first compartment 142, so that the sensor, the circuit board 180, etc. can be protected from the intrusion of rainwater or oil mist. The electrical components of can be protected. Thereby, the reliability of the electric chain block 10 can be ensured for a long period of time.

Further, in the electric chain block 10 of the present embodiment, the amount of slide of the moving member (slide bar 172) that slides in conjunction with the slide member 160 is detected by the sensors (angle sensors 173, 173B, magnetic sensor 178C). Therefore, as compared with the configuration disclosed in Patent Document 1, the sensor can directly detect the slide amount, so that the slide amount detection accuracy can be improved.

Further, in the present embodiment, inside the tubular body 140, an inner tubular chamber 148 is provided below the first partitioned chamber 142 and separated from the partitioned chamber such as the first partitioned chamber 142. .. The operation switch mechanism 150 is attached to the slide ring 171 that slides along the core rod 110 inside the inner cylindrical chamber 148 as the slide member 160 slides, and is attached to the slide ring 171. A slide bar 172 corresponding to a moving member that protrudes into the sliding chamber 145 via 145a and whose slide amount is detected by sensors (angle sensors 173, 173B, magnetic sensor 178C) is provided.

Therefore, the slide bar 172 directly corresponds to the slide of the slide member 160. Therefore, the slide of the slide bar 172 can be accurately detected by the sensors (angle sensors 173, 173B, magnetic sensor 178C). Further, the inner cylinder chamber 148 in which the slide ring 171 slides is located below a compartment such as the first compartment 142 and is separated from this compartment. Therefore, for example, even if the slide member 160 and the slide ring 171 are interlocked with each other by a connecting member such as a connecting pin 176 in order to maintain the interlocking action, a hole portion (elongated hole 147a or the like) for inserting the connecting member. Can be configured to penetrate only the inner cylinder chamber 148. Therefore, the airtightness on the side of the first compartment 142 can be ensured. Accordingly, since the slide bar 172 is configured to project into the sliding chamber 145 located on the upper side (Z1 side) of the inner cylinder chamber 148, working oil or the like may enter the compartments such as the first compartment 142. It almost disappears.

Further, in the present embodiment, the slide ring 171 is elastically supported by the upper spring 174 and the lower spring 175, and the slide ring 171, the slide bar 172, and the slide member 160 return to their initial positions when operated. Can be adopted. When such a configuration is adopted, the slide member 160 is automatically returned to the initial position when not operated, so that it is possible to prevent forgetting to return the slide member 160 to the initial position. Therefore, it is possible to prevent the cylinder operating device 100 from continuing to operate due to the forgetting to return.

In addition, in the present embodiment, the tubular body 140 is provided on the electrical component storage portion 141 having a compartment such as the first compartment 142, and on the lower side (Z2 side) of the electrical component storage portion 141, and the core rod. The distance from 110 to the outer peripheral surface is provided shorter than that of the electrical component storage portion 141, and the slide guide portion 147 on which the slide member 160 slides along the outer peripheral surface, and the lower side (Z2 side) of the slide guide portion 147. The lower cover portion 149 is provided, and the distance from the core rod 110 to the outer peripheral surface is longer than that of the slide guide portion 147.

For this reason, with the slide guide portion 147 sandwiched therebetween, there are the electrical component storage portion 141 and the lower cover portion 149 above and below which the distance from the core rod 110 to the outer peripheral surface is larger than that of the slide guide portion 147. .. Therefore, when the slide member 160 slides along the slide guide portion 147 in which the distance from the core rod 110 to the outer peripheral surface is shorter than that of the electrical component storage portion 141, the vertical range of the slide can be defined. That is, the tubular body 140 can define the upper limit and the lower limit of the slide member 160 while having a simple structure.

Further, in the present embodiment, a lower hook 80 for loading a load is detachably attached to the core rod 110 via the detachable metal fitting mechanism 70, and the detachable metal fitting mechanism 70 rotatably supports the lower hook 80. doing. Therefore, the attachment of the lower hook 80 to the core rod 110 is facilitated.

Further, in the present embodiment, the sensor is the angle sensor 173 that includes the rotating shaft 173a that rotates according to the slide amount of the slide bar 172, and that detects the rotating amount of the rotating shaft 173a. Therefore, the slide of the slide member 160 and the slide bar 172 can be accurately converted into the rotation amount of the rotation shaft 173a of the angle sensor 173. Therefore, the detection accuracy of the slide amount can be improved with a simple configuration.

Further, in the present embodiment, the sensor is the magnetic sensor 178C that detects a change in the magnetic field corresponding to the slide amount of the slide bar 172. Therefore, it is possible to improve the detection accuracy while making the sensor body 178C1 and the magnet 178C2 non-contact with each other. In particular, unlike the case where the angle sensor 173 is used, it is not necessary to form a hole for inserting the rotation shaft 173a between the first partitioned chamber 142 and the sliding chamber 145. Airtightness can be further improved.

<Modification>
Although the respective embodiments of the present invention have been described above, the present invention can be variously modified other than this. This will be described below.

In the above-described embodiment, the case where the angle sensors 173, 173B and the magnetic sensor 178C are used as the sensors has been described. However, the sensor is not limited to these. For example, various sensors such as an ultrasonic sensor and an eddy current sensor can be used.

As such another sensor, for example, there is one shown in FIG. FIG. 8 shows a configuration in which the non-contact distance measuring sensor 179D is provided. That is, the sensor is the non-contact distance measuring sensor 179D that measures the moving distance of the slide ring 171. At this time, the operation switch mechanism 150 includes a slide ring 171 that slides along the core rod 110 inside the inner cylindrical chamber 148 as the slide member 160 slides and that corresponds to the moving member.

Here, the non-contact distance measuring sensor 179D is a sensor for measuring the distance to the object in a non-contact manner by using measurement light such as laser light. In the configuration shown in FIG. 8, the non-contact distance measuring sensor 179D may be provided in the first partitioned chamber 142, but may be provided in the sliding chamber 145 or the second partitioned chamber 143. A window 145b is provided below the first compartment 142. The window portion 145b is a portion that can transmit the measurement light. The window portion 145b capable of transmitting the measurement light may be an opening portion such as the insertion hole 145a, or may have a configuration in which a transparent member capable of transmitting the measurement light is attached to the opening portion.

With such a configuration, the measurement light emitted from the non-contact distance measuring sensor 179D is reflected by the slide ring 171, and then received by the non-contact distance measuring sensor 179D, whereby the non-contact distance measuring sensor 179D. The distance between the slide ring 171 and the slide ring 171 can be measured. Therefore, it is possible to detect the slide amount of the slide ring 171 and the slide member 160 with high accuracy, without using a complicated mechanism and having a simple structure. In this configuration, the slide ring 171 corresponds to the moving member.

Here, the non-contact distance measuring sensor 179D is not limited to the configuration attached to the sliding chamber 145. For example, a configuration in which the inner cylinder chamber 148 is attached to the upper side or the lower side may be adopted. Further, the non-contact distance measuring sensor 179D may be configured to be attached to the slide ring 171, or may be configured to slide together with the slide member 160. When such a configuration is adopted, the non-contact distance measuring sensor 179D may detect the upper surface or the bottom surface of the inner cylindrical chamber 148.

Further, in the above-described embodiment, the angle sensors 173 and 173B describe the method of rotating the rotating shaft 173a by the rack and pinion and the method of rotating the rotating shaft 173Ba by the rotating arm 177B. However, when using the angle sensors 173 and 173B, other methods may be used. For example, the rotating shafts 173a and 173Ba may be rotated using a cam or a link.

10...Electric chain block, 20...Upper hook, 30...Chain block body, 40...Motor, 50...Bucket, 60...Rotating hook, 70...Detachable metal fitting mechanism, 71...Coupling part, 72...Male screw part, 80...Down Hook, 81... Opening portion, 82... Hook latch, 83... Rotating shaft, 90... Cable, 91... Bellows portion, 100... Cylinder operating device (corresponding to operating device), 110... Core rod, 120... Upper bracket, 130 ... connecting fitting, 131... connecting part, 132... joint part, 133... female screw part, 140... cylindrical body, 140M1, 140M2... resin molded body, 141... electrical component storage part, 142... first compartment (compartment compartment) , 143... Second partitioned chamber, 144... Core rod mounting chamber, 145... Sliding chamber (corresponding to partitioned chamber), 145a... Insertion hole, 145b... Window part, 146... Communication hole, 147... Slide guide part Reference numeral 147a... Long hole, 148... Inner cylinder chamber, 149... Lower cover, 150, 150B, 150C... Operation switch mechanism, 160... Slide member, 170... Slide amount detecting mechanism, 171... Slide ring, 172, 172B, 172C ... slide bar (corresponding to moving member), 172a... rack gear portion, 173, 173B... angle sensor (corresponding to sensor), 173a, 173Ba... rotating shaft, 173b... pinion gear, 174... upper spring (corresponding to elastic member), 175 ... Lower spring (corresponding to elastic member), 176... Connecting pin, 177B... Rotating arm, 178C... Magnetic sensor, 178C1... Sensor body, 178C2... Magnet, 179D... Non-contact distance measuring sensor (corresponding to sensor), 180... Circuit board, 200...Emergency stop switch, C1...Load chain

Claims (8)

An operating device for operating a drive of a motor for hoisting and lowering a load chain, comprising:
A core rod that extends in the vertical direction,
A tubular body that covers the core rod and includes a compartment having airtightness inside,
A slide member that is slidable in the axial direction with respect to the tubular body and that can be operated from the entire outer peripheral side of the tubular body is provided, and the drive of the motor is controlled according to the sliding amount of the slide member. Operation switch mechanism to
Equipped with
Inside the tubular body, an inner tubular chamber separated from the partitioned chamber is provided on the lower side of the partitioned chamber,
The operation switch mechanism is
A moving member that interlocks with the slide of the slide member, a sensor that is housed in the compartment and that detects a moving amount of the moving member, and a circuit board that controls the drive of the motor based on a detection signal of the sensor. When,
A slide ring that slides along the core rod inside the inner cylinder chamber as the slide member slides;
A slide bar attached to the slide ring, the upper side of which protrudes into the compartment through an insertion hole, the amount of slide is detected by the sensor, and the slide bar corresponds to the moving member;
An operating device comprising: The slide ring is elastically supported by an elastic member, and the slide ring, the slide bar, and the slide member return to their initial positions when not operated.
The operating device according to claim 1, wherein: The tubular body is
An electrical component storage unit including the compartment,
A slide guide portion provided on the lower side of the electrical component storage portion, the distance from the core rod to the outer peripheral surface being shorter than that of the electrical component storage portion, and the slide member sliding along the outer peripheral surface. When,
A lower cover portion which is provided on the lower side of the slide guide portion and in which the distance from the core rod to the outer peripheral surface is longer than that of the slide guide portion;
The operating device according to claim 1, further comprising: A lower hook for loading a load is detachably attached to the core rod through a detachable metal fitting mechanism,
The detachable fitting mechanism rotatably supports the lower hook,
The operating device according to any one of claims 1 to 3 , wherein: The sensor is an angle sensor that includes a rotation shaft that rotates according to the amount of slide of the slide bar and that detects the amount of rotation of the rotation shaft.
The operating device according to any one of claims 1 to 4 , wherein: The sensor is a magnetic sensor that detects a change in a magnetic field corresponding to a slide amount of the slide bar.
The operating device according to any one of claims 1 to 4 , wherein: An operating device for operating a drive of a motor for hoisting and lowering a load chain, comprising:
A core rod that extends in the vertical direction,
A tubular body that covers the core rod and includes a compartment having airtightness inside,
A slide member that is slidable in the axial direction with respect to the tubular body and that can be operated from the entire outer peripheral side of the tubular body is provided, and the drive of the motor is controlled according to the sliding amount of the slide member. Operation switch mechanism to
Equipped with
The operation switch mechanism is
A moving member that interlocks with the slide of the slide member, a sensor that is housed in the compartment and that detects a moving amount of the moving member, and a circuit board that controls the drive of the motor based on a detection signal of the sensor. When,
Equipped with
Inside the tubular body, an inner tubular chamber separated from the partitioned chamber is provided on the lower side of the partitioned chamber,
The operation switch mechanism includes a slide ring that slides along the core rod inside the inner cylinder chamber as the slide member slides and that corresponds to the moving member.
The sensor is a non-contact short distance sensor that measures a moving distance of the slide ring,
An operating device characterized by the above. While comprising the operating device according to any one of claims 1 to 7 ,
The load chain connected to the upper end side of the operating device,
A lower hook connected to the lower end side of the operating device and for hanging a load,
A motor for hoisting and lowering the load chain,
An electric chain block comprising:

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