The present invention relates to a chain block for use in a load hoisting work.
A chain block is used in general to move a load in an up-down direction. The chain block includes a hand wheel, a wheel cover, a main body portion, and the like. The main body portion is provided with a load sheave around which a load chain is wound. When a hand chain wound around the hand wheel is wound up, the hand wheel is rotated, and the rotation is transmitted via a predetermined transmission mechanism including gears and the like to the load sheave. Accordingly, the load hung on a lower hook moves in an upper direction. Conversely, when the hand chain is wound down in a state in which the load is located on an upper side, the load moves in a lower direction. An example of such a chain block is disclosed in Patent Literature 1.
In the chain block described in Patent Literature 1, a wheel cover (refer to FIG. 25) is attached to a second main frame and is provided in a shape conforming to arc-like outlines of a first main frame and the second main frame. Also, a gear cover (gear case) is provided to project from the first main frame so as to cover a gear part.
When the chain block is moved or carried, the chain block is dragged in some cases. In general, such dragging is often performed with a load chain side gripped. When the chain block is dragged, the chain block rolls along the arc-like outlines of the first main frame and the second main frame even in a case in which the chain block is installed in an upright posture so that the two frames may contact the ground. In this case, the chain block is subject to impact from the ground and falls with the wheel cover or the gear case facing down, and the wheel cover or the gear case is dragged on the ground in this posture. This causes the following problem.
First, the case in which the chain block is dragged on the ground with the wheel cover facing down has a problem in which the dragging may cause tip end sides of stay bolts and nuts to be damaged, the nuts and the stay bolts to come off, and the wheel cover to come off. Second, the case in which the chain block is dragged on the ground with the gear case facing down has a problem in which the dragging may cause heads of rivets attaching a name plate to the gear case to be damaged and the rivets to come off. When the rivets come off in this manner, dust and the like will go into rivet holes of the gear case, which has an effect on mesh of gears.
The present invention is achieved based on the above circumstances, and an object thereof is to provide a chain block enabling to maintain a state in which side surfaces of a first frame and a second frame are dragged.
To solve the above problems, according to a first aspect of the present invention, a chain block is provided including a first frame rotatably supporting a load sheave member around which a load chain is wound and rotatably supporting a drive shaft which is rotated separately from the load sheave member, a second frame arranged to be opposed to the first frame and cooperating with the first frame to rotatably support the load sheave member and rotatably support the drive shaft, a wheel cover side structure including a hand wheel around which a hand chain is wound and a wheel cover which covers the hand wheel and residing on an opposite side of the first frame in a direction away from the second frame, and a gear case side structure including a plurality of gear members adapted to transmit a rotation force from the hand wheel via the drive shaft to the load sheave member and a gear case covering the gear member and residing on an opposite side of the second frame in a direction away from the first frame, and each of the first frame and the second frame is provided with a rolling restriction portion restricting rolling along outer circumferences of the first frame and the second frame in a case of a standing posture in which the first frame and the second frame contact an installation part at the same time.
Also, according to another aspect of the present invention, in the aforementioned invention, the rolling restriction portion is preferably configured to contact the installation part at a position spaced as much as a predetermined rolling prevention distance from an outer rim portion of each of the first frame and the second frame at the same time as the outer rim portion.
Further, according to another aspect of the present invention, in the aforementioned invention, a weight of the wheel cover side structure is preferably larger than a weight of the gear case side structure.
Still further, according to another aspect of the present invention, in the aforementioned invention, the gear case preferably includes a gear storage portion in which the gear members are stored, a height of the gear storage portion is preferably set, when the chain block is inclined with a side of the gear storage portion facing down in a state in which rolling of each of the first frame and the second frame is restricted by the rolling restriction portion, to prevent the chain block from being inclined further and prevent the chain block from falling with the gear storage portion facing down, and the gear storage portion preferably contacts the grounding part to cause the gear case to function as a falling prevention portion.
Still further, according to another aspect of the present invention, in the aforementioned invention, a height of the wheel cover is preferably set, when the chain block is inclined with a side of the wheel cover facing down in a state in which rolling of each of the first frame and the second frame is restricted by the rolling restriction portion, to prevent the chain block from being inclined further and prevent the chain block from falling with the wheel cover facing down, and the wheel cover preferably contacts the grounding part to cause the wheel cover to function as a falling prevention portion.
Still further, according to another aspect of the present invention, in the aforementioned invention, the first frame is preferably attached to the gear case in a state of projecting further to an outer circumferential side than the gear case, and the first frame preferably includes a circular portion having an arc-like outer rim portion and a frame projection portion projecting to an outer circumferential side from the circular portion and serving as the rolling restriction portion.
Still further, according to another aspect of the present invention, in the aforementioned invention, in a planar view of the first frame, the first frame is preferably provided with a stretching portion whose projecting amount of the outer rim portion of the first frame with respect to an outer rim portion of the gear case is larger than that of a side of the frame projection portion.
Still further, according to another aspect of the present invention, in the aforementioned invention, the second frame is preferably attached to the wheel cover in a state of projecting further to an outer circumferential side than the wheel cover, and the second frame preferably includes a circular portion having an arc-like outer rim portion and a frame projection portion projecting to an outer circumferential side from the circular portion and serving as the rolling restriction portion.
Still further, according to another aspect of the present invention, in the aforementioned invention, a position of a weighted center in the standing posture preferably resides in a lower position than a weighted center in a falling posture with the wheel cover facing down and a weighted center in a falling posture with the gear case facing down.
According to the present invention, in a chain block, it is possible to maintain a state in which side surfaces of a first frame and a second frame are dragged.
Hereinbelow, a chain block 10 according to an embodiment of the present invention will be described with reference to the drawings.
As illustrated in
Between the first frame 11 and the second frame 12 are situated a part of the load sheave hollow shaft 20, an upper hook 40, guide rollers 42, a fastener 43, a stripper 44, and the like. As illustrated in
As illustrated in
Each of these frame projection portions 111 is a part for preventing rolling of the chain block 10 and a part functioning as a rolling restriction portion as described below. That is, a case in which the chain block 10 is dragged via a load chain C1 when the chain block 10 is in a standing posture in which the first frame 11 and the second frame 12 contact the ground (hereinbelow, such a posture is referred to as a standing posture) is considered. In this case, the chain block 10 almost rolls due to a tensile force via the load chain C1. However, in a case in which the frame projection portions 111 exist as in the present embodiment, such rolling is prevented, and the load chain C1 is dragged with the frame projection portion 111 kept in a state of abutting on the ground.
Meanwhile, in the present embodiment, the three frame projection portions 111 are provided to form an isosceles triangle when linear parts at side edges thereof are connected. However, the frame projection portions 111 may project from the circular portion 110 in any manner as long as the chain block 10 is prevented from rolling when it is dragged, and as long as the chain block 10 is dragged in a state of abutting on the ground. Also, in the present embodiment, although a part on which the chain block 10 is installed (installation part) is regarded as the ground, an installation part other than the ground (such as a floor) may be regarded as the ground.
Also, each of the frame projection portions 111 is provided with an insertion hole 112 in which the stay bolt SB is to be inserted. The three insertion holes 112 in total are provided to form an isosceles triangle when they are connected but may be provided to form an equilateral triangle or an approximately equilateral triangle. Also, the three insertion holes 112 in total may be provided to form a triangle other than the isosceles triangle when they are connected.
As illustrated in
Also, in the case in which the chain block 10 is dragged in a state of the standing posture, the recess 113 does not contact the ground. Thus, the recess 113 functions to keep a distance between a part of the circular portion 110 contacting the ground and a part of the frame projection portion 111 contacting the ground. In this manner, since the circular portion 110 and the frame projection portion 111 contact the ground at separate positions, the chain block 10 is hard to roll when the chain block 10 is dragged in the standing posture.
Meanwhile, the frame projection portion 111 residing on the lower side (Z2 side) is referred to as a frame projection portion 111b as needed. An end surface on the Z2 side of this frame projection portion 111b is a flat portion 111b1 parallel to a Y axis, and providing the flat portion 111b1 enables the chain block 10 to stand by itself without falling. This facilitates carriage, storage, packing, or the like of the chain block 10.
Also, the recesses 113 are provided on both sides in the Y direction of the frame projection portion 111b as well. Providing each of these recesses 113 keeps a distance between a part of the circular portion 110 contacting the ground and a part of the frame projection portion 111b contacting the ground. Thus, the chain block 10 is hard to roll when the chain block 10 is dragged in the standing posture. In the following description, the recess 113 adjacent to the frame projection portion 111a is referred to as a recess 113a while the recess 113 on each side of the frame projection portion 111b is referred to as a recess 113b.
As illustrated in
Also, as illustrated in
The load gear 31 is provided with a center hole 31a in which the aforementioned gear fitting portion 22 is inserted. In addition, as illustrated in
Meanwhile, the load gear 31, the speed reducing gear member 60, and a pinion gear 72 correspond to a gear member.
Also, the load sheave hollow shaft 20 has a pair of flange portions 23a constituting a load sheave 23 and further has between the flange portions 23a as the pair a chain pocket 23b (refer to
Also, the load sheave hollow shaft 20 is provided with a hollow hole 24. A drive shaft 70 is inserted in the hollow hole 24, and at an end portion of the hollow hole 24 on a side of the second frame 12 is provided a bearing step 26 adapted to receive a bearing B3 pivotally supporting the drive shaft 70. At an end portion of the hollow hole 24 on a side of the gear fitting portion 22 is provided a housing recess 27 adapted to receive a flange portion 71 of the drive shaft 70. Situating the flange portion 71 of the drive shaft 70 in this housing recess 27 shortens a length of the drive shaft 70 along the axial direction (X direction) and can reduce a dimension of the chain block 10 along the X direction (axial direction of the drive shaft 70). Also, shortening the chain block 10 along the axial direction of the drive shaft 70 enables strength of the drive shaft 70 to be improved.
As illustrated in
Each of the guide rollers 42 illustrated in
The fastener 43 illustrated in
The stripper 44 illustrated in
Also, as illustrated in
Here, attaching positions of the aforementioned fixing tools 55 and the guide rollers 42 to the first frame 11 have positional relationship as illustrated in
Also, as illustrated in
As illustrated in
Also, the small-diameter gear 62 meshes with the load gear 31 and transmits the drive force transmitted to the speed reducing gear member 60 to the load gear 31 at a second speed reducing ratio. Meanwhile, this small-diameter gear 62 and the aforementioned large-diameter gear 61 are integrally formed by means of cold forging, for example. However, the small-diameter gear 62 and the large-diameter gear 61 may be integrally formed by means of combination of other processes such as precision forging and cutting or may be formed by forming them separately by means of combination of the above processes and then connecting them.
As illustrated in
As illustrated in
At a part of this drive shaft 70 projecting from the hollow hole 24 to the side of the gear case 13 (X2 side) is provided the pinion gear 72 (corresponding to a first gear) meshing with the aforementioned large-diameter gear 61. In
Meanwhile, in the case in which the tooth thickness Da2 of the tooth tip 722 is set to be larger than the tooth thickness Db2 of the conventional tooth tip 722H as described above, the tooth thickness Da of each tooth 721 can be as follows. That is, in the pinion gear 72 according to the present embodiment, a dimension Ba (not illustrated) of a tooth bottom 723 residing between the adjacent teeth 721 is set to be smaller than a dimension Bb (not illustrated) of a tooth bottom 723H of the conventional pinion gear 72H. Thus, on a side of the tooth bottom 723, the tooth thickness Da (hereinbelow, the tooth thickness Da on the side of the tooth bottom 723 is referred to as a tooth thickness Da1 as illustrated in
In addition, as illustrated in
It is to be noted that the tooth thickness Da of each tooth 721 may be set as follows. That is, the tooth thickness Da1 on the side of the tooth bottom 723 may be set to be approximately equal to the tooth thickness Db1 of the conventional tooth 721H on the side of the tooth bottom 723H. However, in this case, it is necessary to prevent undercut from being generated on the side of the tooth bottom 723. It is to be noted that, in the case in which the tooth thickness Da1 on the side of the tooth bottom 723 is set to be approximately equal to the tooth thickness Db1 of the conventional tooth 721H on the side of the tooth bottom 723H as described above, a dimension of the thickened portion 724 may be set to increase from the tooth bottom 723 to the tooth tip 722.
Also, each tooth 611 of the large-diameter gear 61 meshing with the aforementioned pinion gear 72 is thinned to the extent of thickening of the thickened portion 724 of the tooth 721. That is, in the large-diameter gear 61, a tooth thickness Dc (refer to
Meanwhile, in the configuration illustrated in
Also, each of the speed reducing gear member 60 and the drive shaft 70 is made of a metal and is preferably made of an iron-based metal from a viewpoint of abrasion resistance. Also, the speed reducing gear member 60 and the drive shaft 70 are preferably made of similar materials. However, at least the pinion gear 72 out of the drive shaft 70 may be made of a material more excellent in abrasion resistance than that of the large-diameter gear 61 of the speed reducing gear member 60.
At the part of the drive shaft 70 projecting from the hollow hole 24 to the side of the gear case 13 (X2 side) is provided the pinion gear 72 (corresponding to a gear portion) meshing with the aforementioned large-diameter gear 61. As illustrated in
Here, the tooth thickness on the tip end side of the tooth of the pinion gear 72 is set to be larger than the tooth thickness on the tip end side of the large-diameter gear 61 meshing with the pinion gear 72. Accordingly, lifetime of the pinion gear 72 can be extended. That is, since the number of teeth of the pinion gear 72 is smaller than the number of teeth of the large-diameter gear 61, the number of times of sliding of the respective teeth of the pinion gear 72 is larger than that of the respective teeth of the large-diameter gear 61. Thus, the respective teeth of the pinion gear 72 are abraded earlier than the respective teeth of the large-diameter gear 61. However, by setting the tooth thickness on the tip end side of the tooth of the pinion gear 72 to be larger than the tooth thickness on the tip end side of the large-diameter gear 61 and setting the tooth width to be larger, lifetime of the pinion gear 72 can be extended.
Also, further on the side of the gear case 13 (X2 side) than the pinion gear 72 in the drive shaft 70 is provided a pivotally supporting portion 75. The pivotally supporting portion 75 is a part to which the bearing B5 is attached on an outer circumferential side thereof, and this bearing B5 is attached to a bearing attaching portion 13b provided in the gear case 13. Accordingly, an end portion on the X2 side of the drive shaft 70 is rotatably supported by the gear case 13 via the bearing B5. Further, on the side of the hand wheel 80 in the drive shaft 70 is provided a male screw portion 76. The male screw portion 76 is a part by which a female screw portion 81 of the hand wheel 80 and a female screw portion 91a of a brake receiver 91 are screwed. At an end portion on the X2 side of the male screw portion 76 is provided a step 77, and the below-mentioned brake receiver 91 is locked by this step 77. Also, further on the X1 side than the male screw portion 76 is provided a stopper receiving portion 78 having a pin hole 78a, and a below-mentioned wheel stopper 84 is arranged on this stopper receiving portion 78 and is prevented from coming off by a stopper pin 79.
As illustrated in
In the present embodiment, the attaching plate portion 130 is formed in a similar shape to the aforementioned shape formed by connecting the linear parts of the three frame projection portions 111. However, when the chain block 10 is dragged, the first frame 11 rather than the gear case 13 is preferably dragged. For this reason, the attaching plate portion 130 is provided so that, around each of the frame projection portions 111, the frame projection portion 111 may project further outward than the attaching plate portion 130.
As illustrated in
As illustrated in
Also, as illustrated in
As illustrated in
Also, the brake mechanism 90 includes main components such as the brake receiver 91, brake plates 92, a ratchet wheel 94, and pawl members 95 and the like. As illustrated in
The brake plate 92 (92a) is situated between the flange portion 91b and the below-mentioned ratchet wheel 94 and applies a large friction force between the flange portion 91b and the below-mentioned ratchet wheel 94 in a case of being pressed from the side of the hand wheel 80, and this large friction force brings about a state in which the brake receiver 91 is rotated integrally with the ratchet wheel 94. Meanwhile, the brake plate 92 (92b) is arranged between the ratchet wheel 94 and the hand wheel 80 as well and applies a large friction force between the ratchet wheel 94 and the hand wheel 80 due to press from the side of the hand wheel 80, and this large friction force brings about a state in which the hand wheel 80 is rotated integrally with the ratchet wheel 94.
As illustrated in
Also, the pawl members 95 are provided as a pair, and in the configuration illustrated in
The wheel cover 14 is a member covering an upper side of the hand wheel 80 and an upper side of the brake mechanism 90 (refer to
Meanwhile, the flange portion 141 is bent at an angle to be approximately perpendicular to the side surface portion 142, but in a state in which the wheel cover 14 is attached, the side surface portion 142 is not necessarily perpendicular to the second frame 12. Hence, the flange portion 141 may be bent at an angle to be perpendicular to the side surface portion 142 but does not always have to be bent perpendicularly.
Also, the wheel cover 14 illustrated in
The side surface portion 142 is a part connecting the flange portion 141 with an outer rim portion of the end surface portion 143 and is formed to have a large dimension in a direction of approaching to and separating from the second frame 12 (X direction) as illustrated in
From a cut-out portion 144 between the upper side surface portion 142a and the lower side surface portion 142b, the hand chain C2 can be extended. Also, a right-left side surface portion 145 is provided at a part further on a side of the end surface portion 143 than the cut-out portion 144. The right-left side surface portion 145 is a part extending from the end surface portion 143 toward the second frame 12 in a similar manner to the upper side surface portion 142a and the lower side surface portion 142b and has a length toward the second frame 12 set to be significantly shorter than those of the upper side surface portion 142a and the lower side surface portion 142b due to the presence of the cut-out portion 144.
Also, the end surface portion 143 is a part of the wheel cover 14 opposed to the hand wheel 80. This end surface portion 143 is provided to be continuous with the upper side surface portion 142a, the lower side surface portion 142b, and the right-left side surface portion 145 at the outer rim portion thereof. The end surface portion 143 also has large dimensions in the Y direction and a Z direction (corresponding to a dropping direction) in
Also, as illustrated in
In the present embodiment, the triangular portion T2 is provided to form an isosceles triangle in which a base is located on an upper side while a vertex is located on a lower side but may be provided to form an equilateral triangle or an approximately equilateral triangle. Also, the triangular portion may be provided to form a triangle other than the isosceles triangle.
Here, as is apparent from
As illustrated in
As illustrated in
In a configuration illustrated in
Here, in a conventional wheel cover 14H illustrated in
To be specific in this respect, in a conventional configuration illustrated in
Here, states in which an external force acts on the surrounding portion 148 and the end surface portion 143 are illustrated in
Also, as illustrated in
Meanwhile, a space between the end portion of the guide curved portion 149a and the flange portion 80a is preferably smaller than a diameter of the metal ring C2a of the hand chain C2. In the case of such a configuration, the hand chain C2 is prevented from coming off of the chain pocket 82 even when the hand chain C2 moves significantly (even when the hand chain C2 is deflected).
Also, the leg portion 149b has an end portion thereof on the X2 side provided at a similar position of the flange portion 141 to enable a surface of the end portion thereof to contact the second frame 12. Also, the surface of the end portion of the leg portion 149b is provided with the tip end projection portion 149c. The tip end projection portion 149c is a part to be inserted in an insertion hole 124 (refer to
Here, as illustrated in
(About Configuration for Preventing Falling when Chain Block 10 is Dragged)
Next, in the chain block 10 configured as above, a configuration for preventing falling when the chain block 10 is dragged will be described.
First, in the configuration for preventing falling, the aforementioned frame projection portions 111 and 121 are provided. Providing these frame projection portions 111 and 121 prevents the first frame 11 and the second frame 12 from rolling along the circumferential directions and enables velocity generated by rolling of the chain block 10 to be decreased.
Also, as illustrated in
b≧a (Equation 1)
In the chain block 10, the dimension a is a length between end portions of the outer rim portions in the Y direction of the first frame 11 and the second frame 12. Also, the dimension b is a length between end portions in the X direction of the chain block 10. In this case, the dimension b is a dimension from an edge portion on the X1 side of the protrusion 143a to an edge portion on the X1 side of the gear case 13. However, the dimension b may be a dimension from a flat part of the end surface portion 143, not the edge portion on the X1 side of the protrusion 143a, to an edge portion on the X1 side of the gear case 13 or may be a dimension with reference to other parts (such as an internal wall surface on the X1 side of the wheel cover 14 and an internal wall surface on the X2 side of the gear case 13).
Also, the chain block 10 is configured so that a weight W1 of the side of the gear case 13 and a weight W2 of the side of the wheel cover 14 may have the following relation.
W2≧W1 (Equation 2)
Meanwhile, in relation to (Equation 2), the side of the gear case 13 and the side of the wheel cover 14 may have relation in which moment acting on the side of the wheel cover 14 is larger than moment acting on the side of the gear case 13. Also, any part that is attached to the first frame 11 and whose weight is added to the weight W1 of the side of the gear case 13 corresponds to a gear case side structure while any part that is attached to the second frame 12 and whose weight is added to the weight W2 of the side of the wheel cover 14 corresponds to a wheel cover side structure.
Also, a height of the gear storage portion 131 is configured in the following manner That is, when the chain block 10 is inclined with the side of the gear storage portion 131 facing down and is dragged as it is, the chain block 10 may fall and contact the ground in a state in which the name plate 132 is opposed to the ground.
Here, the chain block 10 is most likely to fall in a case illustrated in
Similarly, a part on the side of the frame projection portion 111a that will contact the ground is referred to as a contact part Q12, a part of the outer rim portion of the first frame 11 that will contact the ground with the recess 113a interposed between the contact part Q12 and this part is referred to as a contact part Q22, and a straight line connecting the contact part Q12 with the contact part Q22 is referred to as a straight line P2. In this case, a contact part Q32 on the side of the gear storage portion 131 that will contact the ground at the same time as the contact parts Q12 and Q22 resides on a straight line perpendicular to the straight line P2. Here, as is apparent from
Hereinbelow, the inclination of the chain block 10 in the case in which the contact parts Q11, Q21, and Q31 contact the ground is considered. In this case, to prevent the chain block 10 from being further inclined, a height S of the gear storage portion 131 has only to be sufficiently long. That is, the longer the height S of the gear storage portion 131 is, the smaller the inclination angle □ of the chain block 10 becomes. Accordingly, the height S of the gear storage portion 131 may be set in a direction in which a ceiling surface (surface to which the name plate 132 is attached) of the gear storage portion 31 will contact the ground as long as to prevent the chain block 10 from further rolling. Meanwhile, the height S may be a height at the contact part Q31 that will contact the ground from the first frame 11 to the gear storage portion 131.
Here, as illustrated in
A case in which the chain block 10 is inclined with the gear storage portion 131 facing down in a state in which the frame projection portion 111a abuts on the ground to prevent rolling is considered. As described above, the distance K1 between the straight line P1 and the contact part Q31 is longer than the distance K2 between the straight line P2 and the contact part Q32 (refer to
Similarly, the chain block 10 is more difficult to fall when the chain block 10 is inclined with the wheel cover 14 facing down in a state in which the frame projection portion 121a or the frame projection portion 121b abuts on the ground to prevent rolling than in the state in which the frame projection portion 111b abuts on the ground to prevent rolling.
This respect will be described. As illustrated in
Moreover, as is apparent from
Similarly, a part on the side of the frame projection portion 121a that will contact the ground is referred to as a contact part Q14, a part of the outer rim portion of the second frame 12 that will contact the ground with the recess 123a interposed between the contact part Q14 and this part is referred to as a contact part Q24, and a straight line connecting the contact part Q14 with the contact part Q24 is referred to as a straight line P4. In this case, a contact part Q34 on the side of the wheel cover 14 that will contact the ground at the same time as the contact parts Q14 and Q24 resides on a straight line perpendicular to the straight line P4. However, a distance K4 between the straight line P4 and the contact part Q34 is shorter than the aforementioned distance K1. Moreover, as described above, the distance K5 is equal to or longer than the distance K6. Accordingly, the chain block 10 is more difficult to fall when the chain block 10 is inclined with the side of the wheel cover 14 facing down in the state in which the frame projection portion 121a abuts on the ground to prevent rolling than in the state in which the frame projection portion 111b abuts on the ground to prevent rolling.
Meanwhile, the contact parts Q11 to Q14 are configured to contact the ground at the same time as the contact parts Q21 to Q24 at positions spaced as much as predetermined rolling prevention distances from the contact parts Q21 to Q24. Accordingly, the contact parts Q11 to Q14 function as rolling restriction portions.
(1) About Action when Load is Raised or Lowered with Use of Chain Block 10
Action when a load is raised or lowered with use of the chain block 10 configured as above will be described below. In a case of raising a load with use of the aforementioned chain block 10, when the hand chain C2 is operated in the upward winding direction in a state in which the load is hung on the lower hook 45, the hand wheel 80 is rotated. At this time, due to mesh of the female screw portion 81 with the male screw portion 76 of the drive shaft 70, the hand wheel 80 travels in a direction (direction toward the X2 in
Conversely, in a case in which the load being hoisted is lowered, the hand chain C2 is fed in a reverse direction of a direction when the load is hoisted. This causes the hand wheel 80 to loosen the press toward the brake plate 92b. The drive shaft 70 is rotated in a reverse direction of the upward winding direction of the load as much as the loosened amount. Thus, the load is gradually lowered.
Meanwhile, in a stop state of the ratchet wheel 94, the tip end of each pawl member 95 meshes with the tooth portion 94a of the ratchet wheel 94. Also, even when one takes one's hand off the hand chain C2 at the time of upward winding and tries to reversely rotate the drive shaft 70 by means of gravity of the load, the brake plate 92b is pressed to the ratchet wheel 94 by the hand wheel 80, and the brake plate 92a is pressed to the flange portion 91b of the brake receiver 91 by the ratchet wheel 94 in a state in which the hand wheel 80 is not rotated. Thus, a brake force against the gravity of the load is applied, and the load is prevented from being lowered.
(2) About Operations when Chain Block 10 is Dragged
Next, operations when the aforementioned chain block 10 is dragged will be described below. In a case in which a user drags the chain block 10 in a state of gripping the load chain C1, the chain block 10 is dragged in the standing posture in which the first frame 11 and the second frame 12 contact the ground, in a posture in which the ceiling surface of the gear case 13 faces down, or in a posture in which the protrusion 143a of the wheel cover 14 faces down.
Here, in the case in which the chain block 10 is dragged in the falling posture in which the ceiling surface of the gear case 13 faces down, an action point of a force to the chain block 10 by the load chain C1 is located further on an upper side than the protrusion 143a. In addition, the weight W2 of the side of the wheel cover 14 resides further on the upper side than the protrusion 143a. Hence, the weight W2 resides in a higher position than the center of the entire chain block 10 (between the first frame 11 and the second frame 12), which brings about an unbalanced state. Accordingly, as the chain block 10 is dragged, the chain block 10 eventually gets in the standing posture.
Also, in the case in which the chain block 10 is dragged in the falling posture in which the wheel cover 14 faces down, the action point of the force to the chain block 10 by the load chain C1 is located on the upper side, and the weight W1 of the side of the gear case 13 resides further on the upper side. Hence, the weight W1 resides in a higher position than the center of the entire chain block 10, which brings about an unbalanced state. Accordingly, as the chain block 10 is dragged, the chain block 10 eventually gets in the standing posture.
According to the aforementioned (Equation 1), the dimension b of the chain block 10 in the X direction is equal to or longer than the dimension a of the chain block 10 in the Y direction. In this case, the chain block 10 is configured so that a position of a weighted center may be lower in the standing posture than in the falling posture in which the ceiling surface of the gear case 13 faces down and in the falling posture in which the wheel cover 14 faces down. Also, in the standing posture, no weight body (such as the weight W1 and the weight W2) exists in a higher position than the weighted center in the standing posture, in contrast with the case of the falling posture in which the ceiling surface of the gear case 13 faces down and the case of the falling posture in which the wheel cover 14 faces down. Accordingly, when the chain block 10 is dragged in the standing posture, the posture is stable.
Here, in the case in which the chain block 10 is dragged in the standing posture, the behavior thereof is as follows. First, when the chain block 10 is dragged in the standing posture, the chain block 10 rolls on the ground along the arc shapes of the outer rim portions of the first frame 11 and the second frame 12. However, after slight rolling, any of the frame projection portions 111a, 111b, 121a, and 121b abuts on the ground. This prevents further rolling of the chain block 10.
Here, even when the chain block 10 is further inclined with the gear storage portion 131 facing down in the state in which the frame projection portions 111b and 121b abut on the ground, the gear storage portion 131 contacts the ground at the contact part Q31, and further inclination of the chain block 10 is prevented. Also, as illustrated in
Even in the case in which the chain block 10 is inclined in the reverse direction, that is, even when the chain block 10 is inclined with the wheel cover 14 facing down in the state in which the frame projection portion 121b abuts on the ground, the wheel cover 14 contacts the ground at the contact part Q33, and further inclination of the chain block 10 is prevented. Also, as illustrated in
The chain block 10 repeats inclination either to the side of the gear case 13 or to the side of the wheel cover 14 and return to the standing posture, keeping the state in which the frame projection portions 111b and 121b abut on the ground, and is dragged while being inclined slightly to the right or to the left.
Also, when the chain block 10 is further inclined with the gear storage portion 131 facing down in the state in which the frame projection portions 111a and 121a abut on the ground, or when the chain block 10 is further inclined with the wheel cover 14 facing down in the state in which the frame projection portions 111a and 121a abut on the ground, the behavior thereof is similar to those in the above cases. That is, the chain block 10 repeats inclination either to the side of the gear case 13 or to the side of the wheel cover 14 and return to the standing posture, keeping the state in which the frame projection portions 111a and 121a abut on the ground, and is dragged while being inclined slightly to the right or to the left.
According to the chain block 10 configured as above, it is possible to keep the state in which the side surfaces (outer rim portions) of the first frame 11 and the second frame 12 are dragged.
That is, the first frame 11 and the second frame 12 are provided with the frame projection portions 111a, 111b, 121a, and 121b serving as the rolling restriction portions which restrict rolling of the first frame 11 and the second frame 12 along the outer rims when the chain block 10 is in the standing posture. For this reason, even when the chain block 10 is dragged, any of the frame projection portions 111a, 111b, 121a, and 121b contacts the ground to prevent further rolling of the chain block 10. Accordingly, it is possible to prevent the chain block 10 from falling with the gear case 13 facing down or with the wheel cover 14 facing down due to a case in which the chain block rolls relatively long to cause an increase of velocity or the like as in the conventional chain block, and the chain block 10 can be dragged with the standing posture kept.
Thus, it is possible to prevent heads of the rivets 133 attaching the name plate 132 from being damaged and the rivets 133 from coming off as in the case in which the chain block 10 is dragged with the gear case 13 facing down. Accordingly, it is possible to prevent dust and the like from going into the rivet holes of the gear case 13 and prevent the dust and the like from having an effect on mesh of the various gears.
Also, it is possible to prevent the tip end sides of the stay bolts SB and the nuts N from being damaged, prevent the nuts N and the stay bolts SB from coming off, and prevent the wheel cover 14 from coming off as in the case in which the chain block 10 is dragged with the wheel cover 14 facing down.
Also, in the present embodiment, two points, one from the contact parts Q11 to Q14 and the other from the contact parts Q21 to Q24, contact the ground at the same time in a state of being spaced as much as the predetermined rolling prevention distance. Accordingly, it is possible to prevent rolling of the chain block 10 along the outer rim portion to enable the chain block 10 to be dragged.
Further, in the present embodiment, the weight W2 of the wheel cover side structure is larger than the weight W1 of the gear case side structure. Thus, even when the chain block 10 is inclined with the gear case 13 facing down, the chain block 10 can return to the standing posture due to the action of the weight W2 of the wheel cover side structure. Accordingly, it is possible to prevent the rivets 133 attaching to the gear case 13 from coming off further favorably.
Still further, in the present embodiment, the height of the gear storage portion 131 is set, when the chain block 10 is inclined with the side of the gear storage portion 131 facing down in the state in which rolling of the first frame 11 and the second frame 12 is restricted by the frame projection portions 111a, 111b, 121a, and 121b, to prevent the chain block 10 from being inclined further and prevent the chain block 10 from falling with the gear storage portion 131 facing down. Thus, it is possible to prevent the heads of the rivets 133 attaching the name plate 132 from being damaged and the rivets 133 from coming off as in the case in which the chain block 10 is dragged with the gear case 13 facing down. Accordingly, it is possible to prevent dust and the like from going into the rivet holes of the gear case 13 and prevent the dust and the like from having an effect on mesh of the various gears.
Still further, in the present embodiment, the height of the wheel cover 14 is set, when the chain block 10 is inclined with the side of the wheel cover 14 facing down in the state in which rolling of the first frame 11 and the second frame 12 is restricted by the frame projection portions 111a, 111b, 121a, and 121b, to prevent the chain block 10 from being inclined further and prevent the chain block 10 from falling with the wheel cover 14 facing down. Thus, it is possible to prevent the tip end sides of the stay bolts SB and the nuts N from being damaged, prevent the nuts N and the stay bolts SB from coming off, and prevent the wheel cover 14 from coming off as in the case in which the chain block 10 is dragged with the wheel cover 14 facing down.
Still further, in the present embodiment, the first frame 11 is provided with the circular portion 110 having the arc-like outer rim portion and the frame projection portions 111a and 111b projecting to the outer circumferential side from the circular portion 110 and serving as the rolling restriction portions. By providing the frame projection portions 111a and 111b projecting from the circular portion 110 in this manner, the frame projection portions 111a and 111b can prevent rolling of the chain block 10 favorably as the rolling restriction portions.
Still further, in the present embodiment, in a planar view of the first frame 11, the first frame 11 is provided with the stretching portion 114 whose projecting amount with respect to the outer rim portion of the gear case 13 is larger than those of the sides of the frame projection portions 111a and 111b. Providing such a stretching portion 114 enables a dragged part to be away from an overlapping surface of the first frame 11 and the gear case 13 even in a case in which the chain block 10 is dragged. Here, when the overlapping surface is damaged, a problem in which dust goes into the gear case 13 will occur. However, since providing the aforementioned stretching portion 114 causes the overlapping surface to be away from the dragged part, it is possible to prevent dust from going into the gear case 13.
Still further, in the present embodiment, the second frame 12 is attached to the wheel cover 14 in a state of projecting further to the outer circumferential side than the wheel cover 14. In addition, the second frame 12 also includes the circular portion 120 and the frame projection portions 121a and 121b. Thus, providing the frame projection portions 111a and 111b can prevent rolling of the chain block 10 favorably. In addition, it is possible to make a dragged part away from an overlapping surface of the second frame 12 and the wheel cover 14 even in a case in which the chain block 10 is dragged. Since this causes the overlapping surface to be away from the dragged part, it is possible to prevent dust from going into the wheel cover 14.
Still further, in the present embodiment, the position of the weighted center of the chain block 10 in the standing posture resides in a lower position than the weighted center in the falling posture with the wheel cover 14 facing down and the weighted center in the falling posture with the gear case 13 facing down. Thus, in a case in which the chain block 10 is dragged in the standing posture, the posture can be stabilized. Conversely, when the chain block 10 is dragged in the falling posture with the wheel cover 14 facing down or in the falling posture with the gear case 13 facing down, the chain block 10 is unbalanced and thus easily returns to the standing posture.
Although the embodiments of the present invention have been described above, the present invention can be altered in various manners. Examples thereof will be described below.
In the above embodiment, the first frame 11 is provided with the frame projection portions 111a and 111b while the second frame 12 is provided with the frame projection portions 121a and 121b, and these frame projection portions function as the rolling restriction portions. However, the configuration of each of the rolling restriction portions is not limited to this configuration. For example, the outer rim portion of each of the first frame 11 and the second frame 12 may be provided to be linear to prevent rolling, and the linear outer rim portion may serve as the rolling restriction portion. Also, the outer rim portion of the first frame 11 may contact the ground at any points as long as at least two points in the outer rim portion of the first frame 11 contact the ground at positions spaced as much as a predetermined rolling prevention distance. Similarly, the outer rim portion of the second frame 12 may contact the ground at any points as long as at least two points in the outer rim portion of the second frame 12 contact the ground at positions spaced as much as a predetermined rolling prevention distance.
Meanwhile, as in the case in which the outer rim portion of each of the first frame 11 and the second frame 12 is provided to be linear, the outer rim portion of each of the first frame 11 and the second frame 12 may not be provided with the recesses 113 or 123.
Also, the rolling restriction portion may be configured by attaching a separate member to each of the first frame 11 and the second frame 12. Similarly, the falling prevention portion may be configured by attaching a separate member to each of the first frame 11 and the second frame 12.
Also, in the above embodiment, the chain guide portion 149 is provided integrally in a state of being continuous with the surrounding portion 148. However, as illustrated in
In such a configuration, flexibility of an arranging position of the chain guide portion 149 to the end surface portion 143 can be improved. Also, even in this configuration, the surrounding portion 148 still exists in the side surface portion 142, and providing the surrounding portion 148 can thus improve strength of the wheel cover 14.
In such a configuration, flexibility of an arranging position of the chain guide portion 149 to the end surface portion 143 can be improved. Also, even in this configuration, the surrounding portion 148 still exists in the side surface portion 142, and providing the surrounding portion 148 can thus improve strength of the wheel cover 14.
In the above embodiment, the configuration in which the auxiliary plate 50 is fixed on the first frame 11 by means of the fixing holes 53 and the fixing tools 55 is described. However, instead of the combination of the fixing holes 53 and the fixing tools 55, at least one combination of a boss hole and a boss may be used, or the auxiliary plate 50 may be fixed on the first frame 11 by means of welding or the like.
Number | Date | Country | Kind |
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2012-262616 | Nov 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/081778 | 11/26/2013 | WO | 00 |