JP2003182970A - Fixing member for lifting used in concrete product - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fixing member of a concrete product C capable of reducing the number of parts to facilitate the manufacture and assembly work and reducing cost. <P>SOLUTION: Lifting force holding parts 13b, 13c are integrally formed on an inner face of a housing cylindrical part 13a of the fixing member 13. Locking recessed parts 13d, 13e are formed on a lower face side of the lifting force holding parts 13b, 13c. A leaving prevention projection 13j is integrally formed on an outer peripheral face of the housing cylindrical part 13a. The whole fixing member 13 is integrally formed by synthetic resin. When a length in the axial direction of the lifting force holding parts 13b, 13c is L1, a length in the direction of axial line of an insertion hole 131 is L2, and the whole length of the housing cylindrical part 13a is L1+L2, dimensional ratio R=L1/(L1+L2) is set to R=0.28 to 0.67. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hoisting fixing member used for concrete products.

2. Description of the Related Art Conventionally, as a concrete product hoisting tool for hoisting a concrete product such as a gutter lid from a vertical direction, a device shown in FIG. 14 has been proposed. This hoisting tool includes a fixing member 31 which is embedded and fixed in a vertical direction in a concrete product C, an engaging metal fitting 32 which is fitted in the fixing member 31, and a cap 33 which closes a lower end opening of the fixing member 31. Is equipped with. Further, the hoisting tool is provided with a hoisting member including a shaft body 34 inserted into the fixing member 31 and locked by the engaging fitting 32, and a ring body 35. The fixing member 31 includes a housing cylindrical portion 31a, an engagement hole 31c formed at a lower end of a through hole 31b formed inside the housing cylindrical portion 31a, and a rotation formed on an inner peripheral surface of the engagement hole 31c. It is provided with a direction restricting portion 31d. Further, a separation preventing protrusion 31e is provided on the outer periphery of the accommodating cylinder portion 31a.
Are formed at a plurality of locations so that the fixing member 31 does not come out upward when the concrete product C is lifted. As shown in FIG. 15, the engaging metal fitting 32 is provided with a guide passage 32a having a substantially horizontally long quadrangular shape in a central portion, and engaging recesses 32b are formed at two positions on both sides thereof. The shaft 34
Is composed of a shaft body 34a, a reduced diameter portion 34b having a diameter smaller than that of the shaft body 34a, and a locking projection 34c integrally formed at a lower end portion of the reduced diameter portion 34b. Then, the shaft 34 is inserted into the through hole 31b from above the fixing member 31 against the elastic force of the spring 36, and the locking projection 34 is formed.
Guide c is moved downward from the guide passage 32a. With the locking projection 34c passing through the guide passage 32a and moved to the rotation allowance space S, the shaft 34 is rotated 90 degrees around the vertical axis to make the locking projection 34c correspond to the locking recess 32b. The shaft 34 is released. Then, the spring 3 that had been lived
6, the state in which the locking projection 34c is engaged with the locking recess 32b is held. Then, when the ring body 35 is lifted by a crane or the like, the concrete product C is lifted by the shaft body 34 and transported to a desired place.

The conventional hoisting tool for concrete products C has the advantage that the shaft 34 can be inserted and locked in the fixing member 31 with one touch. However, since the engaging metal fitting 32 for securing the lifting strength must be fitted into the fixing member 31 as a separate member, the number of parts is increased and the manufacturing and assembling work is troublesome, and the cost is reduced. There was a problem that I could not do it. An object of the present invention is to solve the above problems existing in the prior art and to provide a fixing member for lifting used in a concrete product which can simplify the structure of the fixing member, reduce the number of parts, and reduce the cost. Especially.

In order to solve the above-mentioned problems, the invention according to claim 1 relates to a shaft of a shaft body which constitutes a suspension member with respect to an upper inner peripheral surface of a cylindrical housing cylindrical portion. An insertion hole into which the main body can be inserted is provided, and a guide passage is formed with respect to the lower inner peripheral surface of the accommodating cylinder portion, through which the locking projection provided at the lower end of the shaft can be guided and moved downward. A locking recess formed on the housing cylinder part and formed by a lifting force holding part that receives a lifting force by the locking protrusion, and a locking recess for locking the locking protrusion is provided at a lower end of the lifting force holding part. ,
In the lower outer peripheral surface of the accommodating cylinder portion, in a fixing member for lifting used in a concrete product having a detachment preventing protrusion capable of preventing the accommodating cylinder portion from coming out of the concrete product, in the axial direction of the lifting force holding portion. Length dimension is L
1. If the length of the insertion hole in the axial direction is L2 and the total length of the accommodating cylinder is (L1 + L2), the dimensional ratio R = L1.
/ (L1 + L2) is set to R = 0.28 to 0.67, and the gist is that the accommodating cylinder portion, the lifting force holding portion, and the detachment preventing protrusion are integrally molded of synthetic resin. A second aspect of the present invention is summarized in the first aspect, wherein the dimensional ratio R is set to 0.40 to 0.58. A third aspect of the present invention is summarized in the first aspect, wherein the dimensional ratio R is set to 0.50 to 0.56. The invention according to claim 4 is the invention according to claims 1 to 3.
In any one of the above items, the gist is that the separation preventing protrusion is provided corresponding to substantially the central portion of the lifting force holding portion. According to a fifth aspect of the present invention, in the first aspect, the inner diameter of the insertion hole is connected to the outer diameter of the shaft body of the suspension member and the tip end of the shaft body via a reduced diameter portion. The gist is that the length is set slightly larger than the length of the stop projection. According to a sixth aspect of the present invention, in the first or second aspect, a boss portion that forms a rotation permitting space for the locking projection is integrally formed at a lower end of the accommodating cylinder portion, and a lower end opening thereof is closed by a cap. The main point is what you can do. The invention according to claim 7 relates to claims 1 to 1.
In any one of 6 above, the gist is that a guide portion is provided on the upper surface side of the lifting force holding portion for guiding the locking projection inserted into the insertion hole to a guide passage. According to an eighth aspect of the present invention, in any one of the first to seventh aspects, a rotation restriction is provided on the lower surface side of the lifting force holding portion that rotates the locking projection that has passed through the guide passage in only one direction. The main point is that a section is provided. According to a ninth aspect of the present invention, in any one of the first to eighth aspects, a cap that covers the insertion hole is fitted in an upper end opening of the housing tubular portion. And A tenth aspect of the invention is based on the ninth aspect, and is characterized in that a recess is provided in the flange portion of the cap.

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to FIGS. As shown in FIG. 8, the concrete product C is formed in a heavy-weight thick block shape. The concrete product C is provided with hoisting tools at two places so that it can be lifted in a horizontal state by a crane or the like. Since the lifting equipment has the same configuration, the lifting equipment on one side will be described. As shown in FIG. 1, a hoisting tool 11 for a concrete product C includes a fixing member 13 embedded in the concrete product C and a hanging member 1 formed so as to be engageable with and disengageable from the fixing member 13.
2 and. A cap 14 is fitted to the lower end of the fixing member 13. The fixing member 13
Is a cylindrical cylindrical housing 13a and a cylindrical housing 13
a pair of left and right lifting force holding portions 13b and 13c integrally formed on the lower inner peripheral surface of a, and the lifting force holding portion 13
locking recesses 13d, 13 formed at the lower ends of b, 13c
e and. The locking recesses 13d and 13e are formed by rotation restricting portions 13f and 13g and locking protrusions 13h and 13i. A plurality of separation preventing protrusions 13j are provided on the outer peripheral surface of the accommodating cylinder portion 13a.
The separation preventing projection 13j is formed by the lifting force holding portion 13
It is provided at two positions at positions substantially corresponding to the central portions of b and 13c, and at two positions at positions 90 ° apart from the positions corresponding thereto. Further, the separation preventing projection 13j corresponding to substantially the central portion of the lifting force holding portions 13b and 13c is formed larger than the other separation preventing projections 13j which do not correspond. A boss portion 13k is integrally formed at a lower end portion of the accommodating cylinder portion 13a, and the cap 14 is fitted so as to cover a lower end opening portion of the boss portion 13k.
Inside the boss portion 13k, there are locking protrusions 13h and 13i.
And a bottom surface of the cap 14 define a rotation permitting space S for permitting rotation of a locking projection 15c of a shaft body 15 described later. The vertical length dimension of the lifting force holding portions 13b and 13c is L1, and the axial length dimension of the insertion hole 131 formed in the upper inner peripheral surface of the housing tubular portion 13a is L.
2. The total length of the housing cylinder portion 13a is (L1 + L2). In this embodiment, the dimensional ratio R = L1 / (L1 + L
2) is set in the range of R = 0.28 to 0.67. Further, the separation dimension of the detachment preventing projection 13j corresponding to the lifting force holding portion 13b in the horizontal direction from the outer peripheral surface of the housing cylindrical portion 13a is, for example, 12.5 m.
It is set to m-15.0 mm. Next, the hanging member 12 for lifting the concrete product will be described. This suspension member 12 is a shaft body 15 made of stainless steel.
And a ring body 16 connected to the upper end of the shaft body 15, and a washer 17 fitted to the shaft body 15 so as to be movable in the axial direction.
And a biasing spring 18 that biases the washer 17 downward. The shaft body 15 has a shaft body 15a inserted into the insertion hole 131 of the housing cylinder portion 13a, a reduced diameter portion 15b integrally connected to a lower end (tip) of the shaft body 15a, and the reduced diameter portion 15b. Is provided with a locking projection 15c integrally formed laterally at the lower end of the. The shaft body 15a
A step portion 15d is formed in the middle of the step portion 15d.
A male screw portion 15f is formed on the upper end of the small-diameter connecting shaft portion 15e integrally formed thereabove. A boss portion 16a forming the ring body 16 is screwed into the male screw portion 15f. The boss portion 16a has an annular ring portion 16b.
Are integrally formed. The washer 17 is fitted on the upper side of the step portion 15d so as to be vertically reciprocable along the connecting shaft portion 15e. The spring 1 is provided between the upper surface of the washer 17 and the lower surface of the boss portion 16a.
8 are interposed. An inclined surface 15g is formed at the lower end of the shaft body 15a. Then, the coupling strength between the shaft body 15a and the reduced diameter portion 15b is improved. A guide passage 132 for guiding the locking projection 15c downward in a non-rotating state is formed between the two lifting force holding portions 13b and 13c. The plane shapes of the lifting force holding portions 13b and 13c and the guide passage 132 are as shown in FIG. The set bolt 19 is for fixing the boss portion 16a to the male screw portion 15f. The fixing member 13
The inner diameter dimension D1 of the insertion hole 131 formed inside the housing cylinder portion 13a is slightly larger than the diameter dimension D2 of the shaft body 15a of the shaft body 15. In addition, in FIG.
In Fig. 3, a gap of about 1 mm is drawn between the outer peripheral surface of the shaft main body 15a and the inner peripheral surface of the housing tubular portion 13a, but this gap may be, for example, 0.1 mm to 0.7 mm. The reduced diameter portion 15b is set to a diameter dimension D3 which is smaller than the diameter dimension D2, and the length dimension D4 of the locking projection 15c is equal to or smaller than the diameter dimension D2 and smaller than the diameter dimension D3. It is set large. In this embodiment, the length D4 of the locking projection 15c and the diameter D2 are substantially the same. The operation of lifting the concrete product C by the lifting tool configured as described above will be described. FIG. 1 shows a state in which the suspension member 12 is removed from the fixing member 13 embedded and fixed in the concrete product C, and the guide passage 132 and the locking projection 15c correspond to each other as seen from above as shown in FIG. When the lower end of the shaft body 15 of the hanging member 12 is inserted into the insertion hole 131 of the fixing member 13 in this state, the locking projection 15c reaches the upper end inlet of the guide passage 132. In this state, when the locking projection 15c does not correspond to the guide passage 132, the ring body 16 is rotated to correspond. In this corresponding state, the locking projection 15c is moved downward from the guide passage 132. The lower surface of the washer 17 is brought into contact with the upper surface of the concrete product C in a state in which the locking projection 15c passes through the guide passage 132. When the ring body 16 is further pushed downward against the elastic force of the spring 18, the shaft body 15 is moved downward, and the locking projection 15c is locked by the locking projections 13h and 13h.
It is moved to the lower rotation allowance space S beyond the lower surface of i.
In this state, when the shaft body 15 and the ring body 16 are rotated 90 degrees, the locking projection 15c is rotated 90 degrees. For this reason, as shown in FIG. 2, the locking projection 15c has a locking recess 13d,
It is moved to the position corresponding to 13e. When the pressing of the suspension member 12 is released in this state, the shaft body 15 is pulled up by the action of the spring 18 that has been stored, and FIGS.
As shown in FIG.
Is engaged with. As shown in FIG. 3, when the locking projection 15c is engaged with the locking recesses 13d and 13e, the shaft body 15 does not rotate about its axis, so that the ring body 16 has a wire rope or the like. Lock the concrete product C
Can be lifted upwards. By using a plurality of hoisting tools for one concrete product as shown in FIG. 8, the concrete product can be stably lifted. The fixing member 13 of the hoisting tool 11 is molded using a reinforced synthetic resin formed by mixing glass fiber into 6.6 nylon (for example, Ube Industries, Ltd.). As the glass fiber, one having 30 to 50 mesh is used. Next, the effects of the lifting device configured as described above will be listed together with the configuration. (1) In the above embodiment, the entire fixing member 13 is integrally formed of the reinforced synthetic resin, and the accommodating cylinder portion 13a is formed.
The lifting force holding portions 13b and 13c are provided on the inner peripheral surface of the. The length dimension L1 and the total length dimension L1 + L2 of the containing cylinder portion 13a
The dimensional ratio R of and was set in the range of 0.28 to 0.67. For this reason, the locking projection 15c of the shaft body 15 is engaged with the locking recess 1
When the concrete product C is lifted by engaging with 3d and 13e, it is possible to reliably prevent the lifting force holding portions 13b and 13c from being sheared. In addition, the number of parts can be reduced to one, and the manufacturing can be easily performed by molding, so that the cost can be reduced. By the way, the larger the total length L1 + L2 of the accommodating cylinder portion 13a becomes, the larger the bonding force between the concrete product C and the fixing member 13 becomes, so that a larger concrete product can be lifted. However, in this case, the lifting force holding portions 13b and 13c on the fixing member 13 side are likely to be broken during lifting. Therefore, the lifting force holding portions 13b, 13
In order to prevent the shearing of c, it is necessary to increase the length dimension L1. It is a problem of insufficient strength of the concrete product C that the entire fixing member 13 comes out of the concrete product C due to insufficient bonding strength. Therefore, although it is not a problem of the fixing member 13, the lifting force holding portion 13b,
When shearing occurs at 13c, the concrete product C is dropped. Therefore, it becomes necessary to strictly define the dimension ratio R of the length dimension L1 to the total length dimension (L1 + L2) as described above. When the dimensional ratio R is 0.28 or less, the lifting force holding portions 13b and 13c are always broken. When the dimensional ratio R is larger than 0.67, the concrete strength becomes large, and fracture always occurs on the shaft 15 side. (2) In the above embodiment, the lifting force holding portions 13b, 13
The detachment prevention protrusion 13j corresponding to approximately the center of c is formed large, and the other detachment prevention protrusions 13j are formed small. For this reason, the separation preventing projection 13j that exerts the most shearing force at the time of lifting can be properly coupled to the concrete product C, and the material cost can be reduced. (3) In the above embodiment, the rotation restricting portions 13f and 13g are formed in the locking recesses 13d and 13e. Therefore, by rotating the locking projection 15c of the shaft 15 in one direction within the rotation allowance space S, the locking projection 15c is locked by the locking recess 13d,
13e can be quickly associated and engaged. The above embodiment can be modified as follows. Another example shown in FIGS. 9 to 11 is embodied as a fixing member 13 for a concrete product made of porous concrete. In this another example, the protrusion size of the separation prevention protrusion 13j in the horizontal direction is set to be larger than the same size as the separation prevention protrusion 13j of the above embodiment. A protrusion 13n is integrally formed on the lower end surface of the separation preventing protrusion 13j. Also in this another example, the above-mentioned housing cylinder portion 1
The dimension ratio R of the length dimension L1 of the lifting force holding portions 13b and 13c to the total length dimension (L1 + L2) of 3a is set to R = 0.28 to 0.67, as in the above embodiment. The horizontal extension of the detachment prevention protrusion 13j corresponding to the lifting force holding portions 13b and 13c from the outer peripheral surface of the housing cylinder portion 13a is set to, for example, 25 mm to 30 mm. As shown in FIG. 12, the cap 21 may be fitted into the upper end opening of the accommodating cylinder 13a. The cap 21 includes a main body 21a, an engaging cylinder portion 21b integrally formed on the lower surface of the main body 21a, and a flange portion 21c protruding outward from the engaging cylinder portion 21b. From the fixing member 13 to the cap 21 on the flange portion 21c.
A recess 21e is formed so that a tool can be engaged when the tool is removed. An inclined guide surface 13m for guiding the locking projection 15c to the guide passage 132 is formed on the upper surfaces of the lifting force holding portions 13b and 13c. In this case, the locking projection 15c of the shaft 15 is inserted from the insertion hole 131 into the guide passage 1
When inserting into 32, the guide function works to facilitate the insertion work. As shown in FIG. 13, the inclined surface 15g formed at the lower end of the shaft body 15a of the shaft body 15 may be omitted. In this case, the length L2 of the insertion hole 131 of the fixing member 13 and the distance between the lower end surface of the shaft body 15a and the locking projection 15c can be set to the necessary minimum. Although not shown, the fixing member 13 may be embedded in the concrete product used for the lid of the gutter so as to vertically penetrate, and the cap 14 may be omitted. The dimensional ratio R may be arbitrarily set within the range of 0.40 to 0.58. Further, the dimensional ratio R may be arbitrarily set within the range of 0.50 to 0.56. Further, the dimensional ratio R is set to 0.
You may set arbitrarily in the range of 35-0,67. The fixing member 13 shown in FIG. 1 is used for a concrete product C manufactured from ordinary concrete,
The specific dimensional numerical values of each part are described below. Length dimension L
1 and L2 are both changed (Products a, b, c) are shown in Table 1, and the length dimension L1 is changed in four steps to obtain the length dimension L2.
Table 2 (Products d, e, f,
It is shown in g).

[Table 1]

[Table 2] As is clear from Tables 1 and 2, in the case of a normal concrete product, it is desirable that the dimensional ratio R be arbitrarily set within the range of 0.53 to 0.67. The fixing member 13 shown in FIG. 9 is used for the concrete product C manufactured by porous concrete, and specific dimensional numerical values of each part are described below. Table 3 (Products h, i, j) shows the case where the length dimension L1 is fixed at 36 mm and the length dimension L2 is changed in three steps. Table 4 (Products k, l, m) shows the case where L2 is changed in three stages.

[Table 3]

[Table 4] As is clear from Tables 3 and 4, in the case of a porous concrete product, it is desirable that the dimensional ratio R be arbitrarily set within the range of 0.28 to 0.67. By the way, the lifting force holding portions 13b and 13c of the products a to m shown in Tables 1 to 4 are shown.
The breaking strength of is 31 when the length L1 is 26 mm.
It was 20 kg. As the length dimension L1 increases by 10 mm, the breaking strength increases by about 500 kg.
The fracture strengths of ~ m are 3120 kg, 3370 kg,
3620 kg, 2870 kg, 3120 kg, 3820 kg
kg, 4120 kg, 3620 kg, 3620 kg, 3
620kg, 4120kg, 4120kg, 4120k
It becomes g. Therefore, the weight of the concrete product shared by one fixing member 13 can be concretely calculated from the above-mentioned breaking strength and safety factor (for example, 3 to 10 times). In the above-described embodiment, the locking projections 15c are provided on the outer peripheral portion of the lower end of the reduced diameter portion 15b at two places, and the two guide passages 132 are provided so as to face each other.
May be in one place. Further, the locking projections 15c may be provided at three or four places, and the guide passage 132 may be changed to three or four places. In these cases, if the sum of the contact areas of the locking projections with respect to the lifting force holding portion is the same as the case where the locking projections are provided at two places, the same effect can be obtained by adopting the dimensional ratio R described above. To be Next, technical ideas understood from the respective embodiments configured as described above will be listed below. (Technical idea 1) The fixing member for lifting according to claim 1 or 2, wherein the accommodating cylinder portion of the fixing member has a cylindrical shape and is used for a concrete product. (Definition) In this specification, the separation prevention protrusions include flange-shaped protrusions other than those shown in FIG. 4 or FIG.

As described in detail above, the first to the first aspects of the invention are described.
In the invention described in 0, the number of parts of the fixing member can be reduced and the cost can be reduced.

[Brief description of drawings]

FIG. 1 is a separated sectional view showing an example of a concrete product hoisting tool embodying the present invention.

FIG. 2 is a cross-sectional view showing a state in which the shaft body of FIG. 1 is inserted into a fixing member and rotated.

FIG. 3 is a cross-sectional view showing a state in which the shaft is rotated in the fixing member and the locking projection is engaged with the locking recess.

FIG. 4 is a plan view of a fixing member.

5 is a cross-sectional view taken along the line AA of FIG.

6 is a sectional view taken along line BB of FIG.

FIG. 7 is an exploded perspective view of a fixing member and a hanging member.

FIG. 8 is a perspective view showing a relationship between a concrete product and a lifting tool.

FIG. 9 is a front sectional view of a fixing member showing another example of the present invention.

FIG. 10 is a plan view of the fixing member shown in FIG.

FIG. 11 is a bottom view of the fixing member of FIG.

FIG. 12 is a sectional view showing another example of a fixing member.

FIG. 13 is a cross-sectional view showing another example of the suspension member.

FIG. 14 is a sectional view showing a conventional concrete product lifting tool.

15 is a plan cross-sectional view of the fixing member of FIG. 14 through an engaging fitting.

[Explanation of symbols]

C ... Concrete product, S ... Rotation allowance space, L1, L2
... Length dimension, 13 ... Fixing member, 131 ... Insertion hole, 132
... guide passage, 12 ... suspension member, 13 ... fixing member, 13a ...
Storage cylinder portion, 13b, 13c ... Lifting force holding portion, 13d,
13e ... Locking recesses, 13f, 13g ... Rotation restricting portion, 13
h, 13i ... Locking projection, 13j ... Separation prevention projection, 13l
... lower end opening, 13m ... guide part, 15 ... shaft body, 15a ... shaft body, 15b ... reduced diameter part, 15c ... locking projection, 16 ... ring body, 17 ... washer, 18 ... spring, 21 ... cap.

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[Procedure amendment]

[Submission date] December 20, 2001 (2001.12.
20)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title: Anchoring member for lifting used in concrete products

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hoisting fixing member used for concrete products.

[0002]

2. Description of the Related Art Conventionally, as a concrete product hoisting tool for hoisting a concrete product such as a gutter lid from a vertical direction, a device shown in FIG. 14 has been proposed. This hoisting tool includes a fixing member 31 which is embedded and fixed in a vertical direction in a concrete product C, an engaging metal fitting 32 which is fitted in the fixing member 31, and a cap 33 which closes a lower end opening of the fixing member 31. Is equipped with. Further, the hoisting tool is provided with a hoisting member including a shaft body 34 inserted into the fixing member 31 and locked by the engaging fitting 32, and a ring body 35. The fixing member 31 includes a housing cylindrical portion 31a, an engagement hole 31c formed at a lower end of a through hole 31b formed inside the housing cylindrical portion 31a, and a rotation formed on an inner peripheral surface of the engagement hole 31c. It is provided with a direction restricting portion 31d. Further, a separation preventing protrusion 31e is provided on the outer periphery of the accommodating cylinder portion 31a.
Are formed at a plurality of locations so that the fixing member 31 does not come out upward when the concrete product C is lifted. As shown in FIG. 15, the engaging metal fitting 32 is provided with a guide passage 32a having a substantially horizontally long quadrangular shape in a central portion, and engaging recesses 32b are formed at two positions on both sides thereof.

The shaft body 34 is composed of a shaft body 34a, a reduced diameter portion 34b having a diameter smaller than that of the shaft body 34a, and a locking projection 34c integrally formed at a lower end portion of the reduced diameter portion 34b. There is.

Then, the shaft body 34 is inserted into the through hole 31b from above the fixing member 31 against the elastic force of the spring 36, and the locking projection 34c is guided and moved downward from the guide passage 32a. With the locking projection 34c passing through the guide passage 32a and moved to the rotation allowance space S, the shaft 34 is rotated 90 degrees around the vertical axis to make the locking projection 34c correspond to the locking recess 32b. The shaft 34 is released. Then, the state in which the locking projection 34c is engaged with the locking recess 32b is held by the spring 36 that has been biased. Then, when the ring body 35 is lifted by a crane or the like, the concrete product C is lifted by the shaft body 34 and transported to a desired place.

[0005]

The conventional hoisting tool for concrete products C has the advantage that the shaft 34 can be inserted and locked in the fixing member 31 with one touch. However, since the engaging metal fitting 32 for securing the lifting strength must be fitted into the fixing member 31 as a separate member, the number of parts is increased and the manufacturing and assembling work is troublesome, and the cost is reduced. There was a problem that I could not do it.

An object of the present invention is to solve the problems existing in the above-mentioned conventional techniques, simplify the structure of the fixing member, reduce the number of parts, and reduce the cost. To provide.

[0007]

In order to solve the above-mentioned problems, the invention according to claim 1 relates to a shaft of a shaft body which constitutes a suspension member with respect to an upper inner peripheral surface of a cylindrical housing cylindrical portion. An insertion hole into which the main body can be inserted is provided, and a guide passage is formed with respect to the lower inner peripheral surface of the accommodating cylinder portion, through which the locking projection provided at the lower end of the shaft can be guided and moved downward. A locking recess formed on the housing cylinder part and formed by a lifting force holding part that receives a lifting force by the locking protrusion, and a locking recess for locking the locking protrusion is provided at a lower end of the lifting force holding part. ,
In the lower outer peripheral surface of the accommodating cylinder portion, in a fixing member for lifting used in a concrete product having a detachment preventing protrusion capable of preventing the accommodating cylinder portion from coming out of the concrete product, in the axial direction of the lifting force holding portion. Length dimension is L
1. If the length of the insertion hole in the axial direction is L2 and the total length of the accommodating cylinder is (L1 + L2), the dimensional ratio R = L1.
/ (L1 + L2) is set to R = 0.28 to 0.67, and the gist is that the accommodating cylinder portion, the lifting force holding portion, and the detachment preventing protrusion are integrally molded of synthetic resin.

A second aspect of the present invention is based on the first aspect, wherein the dimensional ratio R is set to 0.40 to 0.58. A third aspect of the present invention is summarized in the first aspect, wherein the dimensional ratio R is set to 0.50 to 0.56.

According to a fourth aspect of the present invention, in any one of the first to third aspects, the separation preventing projection is provided so as to correspond to a substantially central portion of the lifting force holding portion. To do.

According to a fifth aspect of the present invention, in the first aspect, the inner diameter of the insertion hole is connected to the outer diameter of the shaft body of the suspension member and the tip end of the shaft body via a reduced diameter portion. The gist is that the length is set to be slightly larger than the length of the locking projection.

The invention according to claim 6 is the invention according to claim 1 or 2.
In the above, the gist of the present invention is that a boss portion that forms a rotation permitting space of the locking projection is integrally formed at the lower end of the housing cylinder portion, and the lower end opening thereof can be closed by a cap.

According to a seventh aspect of the present invention, in any one of the first to sixth aspects, the locking projection inserted into the insertion hole is guided to the guide passage on the upper surface side of the lifting force holding portion. The main point is that a guide is provided.

According to an eighth aspect of the present invention, in any one of the first to seventh aspects, the locking projection that has passed through the guide passage is rotated only in one direction on the lower surface side of the lifting force holding portion. The gist is that a rotation restricting portion is provided.

According to a ninth aspect of the present invention, in any one of the first to eighth aspects, a cap that covers the insertion hole is fitted in the upper end opening of the accommodating cylinder. That is the summary.

A tenth aspect of the invention is based on the ninth aspect, and is characterized in that the flange portion of the cap is provided with a recess.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to FIGS. As shown in FIG. 8, the concrete product C is formed in a heavy-weight thick block shape. The concrete product C is provided with hoisting tools at two places so that it can be lifted in a horizontal state by a crane or the like.

Since the lifting equipment has the same structure, the lifting equipment on one side will be described. As shown in FIG. 1, a hoisting tool 11 for a concrete product C includes a fixing member 13 embedded in the concrete product C and a hanging member 12 formed so as to be engageable with and disengageable from the fixing member 13. ing. A cap 14 is fitted to the lower end of the fixing member 13.

The fixing member 13 has a cylindrical cylindrical housing portion 13a, and a pair of left and right lifting force holding portions 13b and 13c integrally formed on the lower inner peripheral surface of the cylindrical housing portion 13a.
And locking recesses 13d and 13e formed at the lower ends of the lifting force holding portions 13b and 13c. The locking recesses 13d and 13e are provided with rotation restricting portions 13f and 13g.
And locking protrusions 13h and 13i. A detachment prevention protrusion 13 is provided on the outer peripheral surface of the accommodating cylinder portion 13a.
j is provided at a plurality of locations. This separation prevention protrusion 13
j is provided at two locations at positions corresponding to the substantially central portions of the lifting force holding portions 13b and 13c, and at two locations 90 ° away from the corresponding locations. Further, the separation preventing projection 13j corresponding to substantially the central portion of the lifting force holding portions 13b and 13c is formed larger than the other separation preventing projections 13j which do not correspond.

A boss portion 1 is provided at the lower end of the accommodating cylinder portion 13a.
3k are integrally formed, and the cap 14 is fitted so as to cover the lower end opening of the boss 13k. Inside the boss portion 13k, a rotation allowance space S is formed between the engagement protrusions 13h and 13i and the bottom surface of the cap 14 to allow the engagement protrusion 15c of the shaft body 15 described later to rotate. There is.

The vertical length dimension of the lifting force holding portions 13b and 13c is L1, and the axial length dimension of the insertion hole 131 formed in the upper inner peripheral surface of the accommodating tubular portion 13a is L.
2. The total length of the housing cylinder portion 13a is (L1 + L2). In this embodiment, the dimensional ratio R = L1 / (L1 + L
2) is set in the range of R = 0.28 to 0.67. Further, the separation dimension of the detachment preventing projection 13j corresponding to the lifting force holding portion 13b in the horizontal direction from the outer peripheral surface of the housing cylindrical portion 13a is, for example, 12.5 m.
It is set to m-15.0 mm.

Next, the suspension member 12 for suspending the concrete product will be described. The suspension member 12 includes a shaft body 15 made of stainless steel, a ring body 16 connected to an upper end of the shaft body 15, a washer 17 fitted to the shaft body 15 so as to be movable in the axial direction, and the washer 17 Is constituted by an urging spring 18 for urging downward. The shaft body 15 includes a shaft body 15a inserted into the insertion hole 131 of the housing cylinder portion 13a, a reduced diameter portion 15b integrally connected to a lower end (tip) of the shaft body 15a, and the reduced diameter portion 15
The lower end of b is provided with a laterally integrally formed locking projection 15c. A step 15 is formed in the middle of the shaft body 15a.
d is formed, and a male screw portion 15f is formed at the upper end of the small-diameter connecting shaft portion 15e integrally formed above the step portion 15d. The male thread 15f has the ring body 16
The boss portion 16a constituting the is screwed. Boss 16
An annular ring portion 16b is integrally formed with a. The washer 17 is fitted on the upper side of the step portion 15d so as to be vertically reciprocable along the connecting shaft portion 15e. The upper surface of the washer 17 and the boss portion 1
The spring 18 is interposed between the lower surface of 6a and the lower surface of 6a.
An inclined surface 15g is formed at the lower end of the shaft body 15a. Then, the coupling strength between the shaft body 15a and the reduced diameter portion 15b is improved.

A guide passage 132 for guiding the locking projection 15c downward in a non-rotating state is formed between the two lifting force holding portions 13b and 13c. The plane shapes of the lifting force holding portions 13b and 13c and the guide passage 132 are as shown in FIG.

The set bolt 19 is for fixing the boss portion 16a to the male screw portion 15f. Insertion hole 1 formed inside the accommodating cylinder portion 13a of the fixing member 13.
The inner diameter dimension D1 of 31 is slightly larger than the diameter dimension D2 of the shaft body 15a of the shaft body 15. 2 and 3, the outer peripheral surface of the shaft main body 15a and the housing cylinder portion 13 are
Although a gap of about 1 mm is drawn between the inner peripheral surface of a and this, the gap may be, for example, 0.1 mm to 0.7 mm. The reduced diameter portion 15b is set to a diameter dimension D3 that is smaller than the diameter dimension D2, and the length dimension D4 of the locking projection 15c is the same as or smaller than the diameter dimension D2 and smaller than the diameter dimension D3. It is set large. In this embodiment, the length D4 of the locking projection 15c and the diameter D2 are substantially the same.

The operation of lifting the concrete product C by the hoisting tool configured as described above will be described. FIG. 1 shows a state in which the suspension member 12 is removed from the fixing member 13 embedded and fixed in the concrete product C, and the guide passage 132 and the locking projection 15c correspond to each other as seen from above as shown in FIG. In this state, the shaft body 15 of the hanging member 12
When the lower end of the is inserted into the insertion hole 131 of the fixing member 13,
The locking projection 15c reaches the upper end entrance of the guide passage 132. In this state, when the locking projection 15c does not correspond to the guide passage 132, the ring body 16 is rotated to correspond. In this corresponding state, the locking projection 15c is moved downward from the guide passage 132. The lower surface of the washer 17 is brought into contact with the upper surface of the concrete product C in a state in which the locking projection 15c passes through the guide passage 132. Further, the ring body 16 is replaced by a spring 18
When pushed downward against the resilience of the shaft 15, the shaft 15 is moved downward, and the locking projection 15c is moved to the lower rotation allowance space S beyond the lower surfaces of the locking projections 13h and 13i. In this state, when the shaft body 15 and the ring body 16 are rotated 90 degrees, the locking projection 15c is rotated 90 degrees. For this reason,
As shown in FIG.
Is moved to the position corresponding to. When the pressing of the hanging member 12 is released in this state, the shaft body 15 is pulled up by the action of the spring 18 which has been stored, and the locking projection 15c is locked by the locking recess 13d, as shown in FIGS. 13e is engaged.

As shown in FIG. 3, when the locking projection 15c is engaged with the locking recesses 13d and 13e, the shaft 1 is
5 does not rotate about its axis, so ring 1
The concrete product C can be lifted upward by locking a wire rope or the like to the unit 6. By using a plurality of hoisting tools for one concrete product as shown in FIG. 8, the concrete product can be stably lifted.

The fixing member 13 of the hoisting tool 11 is made of glass fiber of 6.6 nylon (for example, Ube Industries Ltd.).
Molding is performed using a reinforced synthetic resin formed by being mixed with. As the glass fiber, one having 30 to 50 mesh is used.

Next, the effects of the hoisting tool constructed as described above will be listed together with the construction. (1) In the above embodiment, the entire fixing member 13 is integrally formed of the reinforced synthetic resin, and the accommodating cylinder portion 13a is formed.
The lifting force holding portions 13b and 13c are provided on the inner peripheral surface of the. The length dimension L1 and the total length dimension L1 + L2 of the containing cylinder portion 13a
The dimensional ratio R of and was set in the range of 0.28 to 0.67. For this reason, the locking projection 15c of the shaft body 15 is engaged with the locking recess 1
When the concrete product C is lifted by engaging with 3d and 13e, it is possible to reliably prevent the lifting force holding portions 13b and 13c from being sheared. In addition, the number of parts can be reduced to one, and the manufacturing can be easily performed by molding, so that the cost can be reduced.

By the way, as the total length L1 + L2 of the accommodating cylinder portion 13a increases, the concrete product C increases.
Since the binding force between the fixing member 13 and the fixing member 13 is increased, a larger concrete product can be lifted. However, in this case, the lifting force holding portion 13 on the fixing member 13 side
In b and 13c, breakage is likely to occur during lifting. Therefore, in order to prevent the lifting force holding portions 13b and 13c from being sheared, it is necessary to increase the length dimension L1.

It is a problem of insufficient strength of the concrete product C that the entire fixing member 13 is loosely pulled out of the concrete product C because of insufficient bonding strength. Therefore, although it is not a problem of the fixing member 13, the lifting force holding portions 13b, 1
When shearing occurs at 3c, the concrete product C is dropped. Therefore, it becomes necessary to strictly define the dimension ratio R of the length dimension L1 to the total length dimension (L1 + L2) as described above.

When the dimension ratio R is 0.28 or less, the lifting force holding portions 13b and 13c are always broken. When the dimensional ratio R is larger than 0.67, the concrete strength becomes large, and fracture always occurs on the shaft 15 side.

(2) In the above embodiment, the detachment prevention protrusion 1 corresponding to the substantially central portion of the lifting force holding portions 13b and 13c.
3j is formed large, and the other separation preventing projections 13j are formed small. For this reason, the separation preventing projection 13j that exerts the most shearing force at the time of lifting can be properly coupled to the concrete product C, and the material cost can be reduced.

(3) In the above embodiment, the locking recess 13
The rotation restricting portions 13f and 13g are formed on the d and 13e. Therefore, by rotating the locking projection 15c of the shaft body 15 in one direction within the rotation allowance space S, the locking projection 15c can be engaged with the locking recesses 13d and 13e in a quick manner.

The above embodiment can be modified as follows. Another example shown in FIGS. 9 to 11 is embodied as a fixing member 13 for a concrete product made of porous concrete. In this another example, the protrusion size of the separation prevention protrusion 13j in the horizontal direction is set to be larger than the same size as the separation prevention protrusion 13j of the above embodiment. A protrusion 13n is integrally formed on the lower end surface of the separation preventing protrusion 13j.

Also in this other example, the above-mentioned housing cylinder portion 1
The dimension ratio R of the length dimension L1 of the lifting force holding portions 13b and 13c to the total length dimension (L1 + L2) of 3a is set to R = 0.28 to 0.67, as in the above embodiment. The horizontal extension of the detachment prevention protrusion 13j corresponding to the lifting force holding portions 13b and 13c from the outer peripheral surface of the housing cylinder portion 13a is set to, for example, 25 mm to 30 mm.

As shown in FIG. 12, the accommodating cylinder portion 1
The cap 21 may be fitted into the upper end opening of 3a. The cap 21 includes a main body 21a, an engaging cylinder portion 21b integrally formed on the lower surface of the main body 21a, and a flange portion 21c protruding outward from the engaging cylinder portion 21b. The flange portion 21c has a concave portion 2 into which a tool can be engaged when the cap 21 is removed from the fixing member 13.
1e is formed.

An inclined guide surface 13m for guiding the locking projection 15c to the guide passage 132 is formed on the upper surfaces of the lifting force holding portions 13b and 13c. In this case, when the locking projection 15c of the shaft body 15 is inserted into the guide passage 132 from the insertion hole 131, the guide function works to facilitate the insertion work.

As shown in FIG. 13, the inclined surface 15g formed at the lower end of the shaft body 15a of the shaft body 15 may be omitted. In this case, the length L2 of the insertion hole 131 of the fixing member 13 and the distance between the lower end surface of the shaft body 15a and the locking projection 15c can be set to the necessary minimum.

Although not shown, the fixing member 13 may be embedded in the concrete product used for the lid of the gutter so as to vertically penetrate, and the cap 14 may be omitted. The dimensional ratio R may be arbitrarily set within the range of 0.40 to 0.58. Further, the dimensional ratio R may be arbitrarily set within the range of 0.50 to 0.56. Further, the dimensional ratio R is set to 0.
You may set arbitrarily in the range of 35-0,67.

The fixing member 13 shown in FIG. 1 is used for a concrete product C manufactured from ordinary concrete, and concrete dimensional numerical values of each part are described below. Table 1 shows the case where both the length dimensions L1 and L2 are changed (products a, b, c), and the case where the length dimension L1 is changed in four steps and the length dimension L2 is changed in two steps. 2 (Products d, e, f, g).

[0040]

[Table 1]

[0041]

[Table 2]

As is clear from Tables 1 and 2, in the case of a normal concrete product, the dimensional ratio R is 0.53 to.
It is desirable to set it arbitrarily within the range of 0.67. The fixing member 13 shown in FIG. 9 is used for the concrete product C manufactured by porous concrete, and specific dimensional numerical values of each part are described below. Table 3 (Products h, i, j) shows the case where the length dimension L1 is fixed at 36 mm and the length dimension L2 is changed in three steps. Table 4 (Products k, l, m) shows the case where L2 is changed in three stages.

[0043]

[Table 3]

[0044]

[Table 4]

As is clear from Tables 3 and 4, in the case of porous concrete products, the dimensional ratio R is 0.28 to
It is desirable to set it arbitrarily within the range of 0.67. By the way, the lifting force holding portion 1 for each of the products a to m shown in Tables 1 to 4
The breaking strength of 3b and 13c was 3120 kg when the length dimension L1 was 26 mm. This length dimension L1 is 1
Since the breaking strength increases by about 500 kg with each increase of 0 mm, the breaking strengths of the products a to m are 3120 kg and 3 in order.
370kg, 3620kg, 2870kg, 3120k
g, 3820 kg, 4120 kg, 3620 kg, 36
20kg, 3620kg, 4120kg, 4120k
g, 4120 kg. Therefore, one fixing member 13
The weight of the concrete product shared by the above can be concretely calculated from the above-mentioned fracture strength and safety factor (for example, 3 to 10 times).

In the above-described embodiment, the locking projections 15c are provided at two locations on the outer periphery of the lower end of the reduced diameter portion 15b, and the two guide passages 132 are provided so as to face each other. There may be one 132. Also, the locking projection 15
c may be three or four, and the guide passage 132 may be changed to three or four. In these cases, the sum of the contact areas of the locking protrusions with the lifting force holding part is
If the locking projections are provided in two places, the same effect can be obtained by adopting the dimensional ratio R described above.

Next, the technical ideas understood from the respective embodiments configured as described above will be listed below. (Technical idea 1) The fixing member for lifting according to claim 1 or 2, wherein the accommodating cylinder portion of the fixing member has a cylindrical shape and is used for a concrete product.

(Definition) In this specification, the separation prevention protrusions include flange-shaped protrusions other than those shown in FIG. 4 or FIG.

[0049]

As described in detail above, the first to the first aspects of the invention are described.
In the invention described in 0, the number of parts of the fixing member can be reduced and the cost can be reduced.

[Brief description of drawings]

FIG. 1 is a separated sectional view showing an example of a concrete product hoisting tool embodying the present invention.

FIG. 2 is a cross-sectional view showing a state in which the shaft body of FIG. 1 is inserted into a fixing member and rotated.

FIG. 3 is a cross-sectional view showing a state in which the shaft is rotated in the fixing member and the locking projection is engaged with the locking recess.

FIG. 4 is a plan view of a fixing member.

5 is a cross-sectional view taken along the line AA of FIG.

6 is a sectional view taken along line BB of FIG.

FIG. 7 is an exploded perspective view of a fixing member and a hanging member.

FIG. 8 is a perspective view showing a relationship between a concrete product and a lifting tool.

FIG. 9 is a front sectional view of a fixing member showing another example of the present invention.

FIG. 10 is a plan view of the fixing member shown in FIG.

FIG. 11 is a bottom view of the fixing member of FIG.

FIG. 12 is a sectional view showing another example of a fixing member.

FIG. 13 is a cross-sectional view showing another example of the suspension member.

FIG. 14 is a sectional view showing a conventional concrete product lifting tool.

15 is a plan cross-sectional view of the fixing member of FIG. 14 through an engaging fitting.

[Explanation of Codes] C ... Concrete product, S ... Rotation allowance space, L1, L2
... Length dimension, 13 ... Fixing member, 131 ... Insertion hole, 132
... guide passage, 12 ... suspension member, 13 ... fixing member, 13a ...
Storage cylinder portion, 13b, 13c ... Lifting force holding portion, 13d,
13e ... Locking recesses, 13f, 13g ... Rotation restricting portion, 13
h, 13i ... Locking projection, 13j ... Separation prevention projection, 13l
... lower end opening, 13m ... guide part, 15 ... shaft body, 15a ... shaft body, 15b ... reduced diameter part, 15c ... locking projection, 16 ... ring body, 17 ... washer, 18 ... spring, 21 ... cap.

Claims (10)

[Claims] 1. An insertion hole (131) into which a shaft body (15a) of a shaft body (15) constituting a suspension member (12) can be inserted with respect to an inner peripheral surface of an upper part of a cylindrical housing cylinder part (13a). Is provided
A guide passage (132) is formed on the inner peripheral surface of the lower portion of the accommodating tubular portion (13a) to guide and move the locking protrusion (15c) provided at the lower end of the shaft body (15). The passage (132) is formed in the accommodating cylinder portion (13a) and is formed by a lifting force holding portion (13b, 13c) that receives a lifting force by the locking protrusion (15c), and the lifting force holding portion (13b, The lower end of 13c) has locking recesses (13d, 13d) for locking the locking projections (15c).
e), which is provided on the outer peripheral surface of the lower portion of the storage cylinder portion (13a) and has a detachment preventing projection (13j) capable of preventing the storage cylinder portion from coming off from the concrete product. In the member, the axial length dimension of the lifting force holding portions (13b, 13c) is L1, the axial length dimension of the insertion hole (131) is L2, and the total length of the accommodating tubular portion (13a) is ( L1 + L
2), the dimensional ratio R = L1 / (L1 + L2) is set to R = 0.28 to 0.67, and the accommodating cylinder portion (13a), the lifting force holding portions (13b, 13c), and the detachment preventing protrusion ( 13j) is integrally molded of synthetic resin, and is a fixing member for lifting used in concrete products. 2. The dimensional ratio R according to claim 1, wherein the dimensional ratio R is 0.
A fixing member for lifting used for concrete products set to 40 to 0.58. 3. The dimensional ratio R according to claim 1, wherein the dimensional ratio R is 0.
A fixing member for lifting used for a concrete product set to 50 to 0.56. 4. The method according to any one of claims 1 to 3,
The separation preventing protrusion (13j) is provided with a lifting force holding portion (13).
b, 13c) A fixing member for lifting, which is used for a concrete product and is provided corresponding to the substantially central portion. 5. The insertion hole (13) according to claim 1,
The inner diameter (D1) dimension of 1) is the outer diameter (D2) dimension of the shaft body (15a) of the suspension member (12) and the shaft body (15).
A hoisting fixing member used for a concrete product, which is set to be slightly larger than the length (D4) of the locking projection (15c) connected to the tip end of (a) via the reduced diameter portion (15b). 6. The boss portion (13k) according to claim 1 or 2, wherein a boss portion (13k) forming a rotation permitting space (S) of the locking protrusion (15c) is integrally formed at a lower end of the housing cylinder portion (13a). A fixing member for lifting used for a concrete product whose lower end opening can be closed by a cap (14). 7. The method according to any one of claims 1 to 6,
A guide portion (13m) for guiding the locking protrusion (15c) inserted in the insertion hole (131) to the guide passage (132) is provided on the upper surface side of the lifting force holding portion (13b, 13c). A fixing member for lifting used in concrete products. 8. The method according to claim 1, wherein
A rotation restricting portion (13f, 13g) for rotating the locking protrusion (15c) passing through the guide passage (132) only in one direction is provided on the lower surface side of the lifting force holding portion (13b, 13c). A fixing member for lifting used in existing concrete products. 9. The method according to any one of claims 1 to 8,
A fixing member for lifting used for a concrete product, wherein a cap (21) for covering the insertion hole (131) is fitted into an upper end opening of the accommodating cylinder portion (13a). 10. Cap (21) according to claim 9.
A fixing member for lifting, which is used for concrete products, in which a concave portion (21e) is provided in the flange portion (21c).