JP2022082498A - Skeleton keel structure with closed cross-section, and mounting method thereof - Google Patents

Abstract

To provide a skeleton keel structure with a closed cross-section capable of solving a problem that cannot be satisfied by conventional insertion connection mounting method, and a mounting method thereof.SOLUTION: The skeleton keel structure with a closed cross-section includes a stud 1 and a cross beam 2. An insertion hole 11 is formed in a side wall of the stud 1, a pin sleeve 31 and an insertion pin 4 are provided on a connection base 3 in the cross beam 2. A restoration spring 32 is provided to the pin sleeve 31, and the insertion pin 4 is provided with a locking groove 42 and a locking block 42. The inner end of the locking block 42 and the bottom of the locking groove 42 are connected by a first compression spring 43. A position regulation groove 44 is formed on the insertion pin 4, the connection base 3 is provided with an adjustable sleeve 33, the adjustable sleeve 33 is provided with an adjustment block 5 therein, and the adjustment block 5 is formed with an adjustment groove 51. The adjustable sleeve 33 and the pin sleeve 31 are connected by a control tube 35. The control tube 35 is provided with a control rod 6, and a sliding groove 36 is formed. A sliding block 61 and a second compression spring 62 are mounted on the adjusting rod 6.SELECTED DRAWING: Figure 1

Description

The present invention relates to the technical field of panel wall keels, and specifically to a closed cross-section skeleton keel structure and a method for mounting the same.

The keel of the panel wall is formed by connecting the stud and the cross beam. Conventional keels employ open-section agents. Due to the specifications of double glazing, it has become difficult for open-section profiles to meet the requirements, and closed-section profiles have become widely applied, but closed-section profiles are usually connected by insertion with spring bolts. For example, Chinese application 201220312729.9 discloses a new connection structure for panel wall keels, which is inserted and connected by a combination of spring bolts on the cross beam and positioning holes located on the studs, which is a closed-section profile. The connection between the cross beam and the stud is realized. By adopting the insertable connection, the cross beam can be removed in a spiritual and convenient manner, but if there is a part of the keel that must be fixed to the stud to form a high-strength keel skeleton, maintenance can be conveniently performed. There is also a part where the cross beam must be removed for spiritual activity. The plug-in connection alone does not meet the connection demand for the entire keel and needs to be improved.

Chinese application 201220312729.9 specification

In order to solve the above-mentioned problems in the prior art, the present invention adopts a lock type mounting before mounting to realize thorough fixing, or adopts an insertion type connection mounting method to conveniently remove the keel. It is an object of the present invention to provide a closed cross-section skeleton keel structure and a method of mounting the same, which can meet the connection demand of different parts of the body.

A closed-section skeleton keel structure including a stud and a cross beam having a closed-section rectangular tube structure, the side wall of the stud is provided with a plurality of insertion holes, and a connecting base is fixed in the end of the cross beam. The connection base is provided with a plurality of pin sleeves provided along the longitudinal direction of the cross beam, an insertion pin is movably provided in the pin sleeve, and the inner end of the pin sleeve is closed. A repositioning spring is provided in the pin sleeve so that both ends are in contact with the inner end of the insertion pin and the inner end of the pin sleeve, respectively, and the rod wall approaching the outer end of the insertion pin is provided in the depth direction. A locking groove perpendicular to the longitudinal direction of the insertion pin is formed, and a locking block is movably provided in the locking groove so that the inner end of the locking block and the bottom of the locking groove can be connected to each other. The space is connected by a first compression spring, and the portion of the locking block extending from the locking groove has an inclined structure, and the outer end surface of the locking block is inclined toward the outer end of the insertion pin. A position-regulating groove is formed on the rod wall of the insertion pin, and the position-regulating groove has an open groove structure formed along the longitudinal direction of the insertion pin. The inner end groove wall of the above has a slope structure, the length of the groove mouth of the position-regulating groove is larger than the length of the groove bottom, and the central position of the connection base is a cylinder provided along the longitudinal direction of the cross beam. An adjustment sleeve is provided, an adjustment block is movably provided in the adjustment sleeve, a plurality of adjustment grooves are formed on the outer wall of the adjustment block, and the adjustment groove is the circumference of the adjustment block. It has an arcuate open groove structure formed in the direction, and the depth of the groove from the front end to the rear end of the adjustment groove is gradually reduced, and the adjustment sleeve and the plurality of pin sleeves are separated from each other by an adjustment tube. Connected, the longitudinal direction of the control tube is provided perpendicular to the longitudinal direction of the cross beam, and both ends of the control tube are provided through the adjustment sleeve and the pin sleeve, and the inside of the control tube is provided. An adjusting rod is movably provided, a sliding groove is formed on the inner wall of the adjusting pipe, and a sliding block slidably located in the sliding groove is provided on the rod wall of the adjusting rod. The adjusting rod is externally provided with a second compression spring provided at both ends in contact with the outer end of the sliding groove and the sliding block, and the inner and outer ends of the adjusting rod are the second. Since the compression spring pushes the sliding block, it is provided in contact with the groove bottom of the adjusting groove and the inner groove wall of the position limiting groove, respectively.

The end of the cross beam is provided in contact with the side wall of the stud, the plurality of insertion pins are pushed and moved by the repositioning spring to be inserted into the plurality of insertion holes, and the outer end of the adjustment rod is the said. The locking block is located outside the insertion hole when it comes into contact with a position close to the groove opening on the inner groove wall of the position limiting groove. The knob provided at the outer end of the adjustment block rotates or inverts to rotate the adjustment block, and the inner end of the adjustment rod is moved to the front end or the rear end of the adjustment rod of the adjustment rod. The outer end can be moved to a position close to the groove opening on the inner groove wall of the position limiting groove, or to a position close to the groove bottom on the inner groove wall of the position limiting groove.

The keel structure of the present invention mounts the locking block inside the insertion hole by rotating the knob to rotate the adjustment block prior to mounting and then mounting the end of the cross beam to the side wall of the stud. It can be inserted and brought into contact with the inner wall of the stud, which can be thoroughly fixed as a lock-type mounting. The locking block can be located outside the insertion hole by inverting the knob to rotate the adjustment block and mounting the end of the cross beam to the side wall of the stud. This makes it convenient to remove as an insertable connection. For this reason, if you choose the mounting method by rotating the knob before mounting and choose the lock type mounting, you can fix it thoroughly, and if you choose the mounting by the insertion type connection, it will be convenient to remove, which makes it convenient for the keel. The connection method can be selected according to the connection demand of different parts.

The position of the inner groove wall of the position-regulating groove close to the groove bottom has a planar structure and is provided perpendicular to the longitudinal direction of the insertion pin.

Therefore, by reversing the knob, the stable state of the adjusting rod can be maintained, and the adjusting rod is prevented from moving due to too much force of the repositioning spring.

The depth of the adjustment groove is smaller than the depth of both ends, the depth of the adjustment groove is gradually reduced from both ends to the middle portion, and the position regulation groove is at the intersection of the bottom and the inner groove wall. A storage groove is formed by deepening the depth.

Therefore, the knob can be quickly rotated or inverted to avoid the intermediate state.

The connecting base includes a connecting sleeve that is fixedly fitted to the inside of the cross beam, and the connecting sleeve is connected to the pin sleeve and the adjusting sleeve via a cross-shaped reinforcing rib, and the adjusting sleeve is , The control pipe is located at the intersection of the reinforcing ribs.

Therefore, the structure is simple and stable.

The length of the adjusting rod is smaller than the inner diameter of the adjusting sleeve, and the groove opening of the sliding groove is located at the inner end of the adjusting tube.

Therefore, it is convenient to assemble the connection base.

An annular stopper plate is coaxially fixed to the inner wall of the outer end of the adjustment sleeve, and the stopper plate is provided with a support mark for aligning with the knob.

A plurality of locking grooves are formed on the bar wall of the insertion pin that can be operated by the support mark on the stop plate, and the plurality of locking grooves are arranged along the circumferential direction of the insertion pin. To.

The connecting sleeve, the reinforcing rib, the pin sleeve, the adjusting sleeve, and the adjusting tube have an integral structure.

The outer end of the insertion pin has a chamfered or circular angle.

Therefore, the insertion pin can be conveniently inserted into the insertion hole.

It is a mounting method of a closed cross-section skeleton keel structure, and includes a locking type mounting method and a mounting method by insertion connection.

In the lock mounting method, the knob is rotated to rotate the adjustment block, the inner end of the adjustment rod is moved to the front end of the adjustment groove, and the outer end of the adjustment rod is moved to the inner groove wall of the position regulation groove. The cross beam is brought into contact with the side wall of the stud, the repositioning spring pushes the insertion pin, and the plurality of insertion pins are inserted into the plurality of insertion holes. The stop block is inserted inside the insertion hole and abuts on the inner wall of the stud.

In the mounting method by the insertion connection, the knob is inverted to rotate the adjustment block, the inner end of the adjustment rod is moved to the rear end of the adjustment groove, and the outer end of the adjustment rod is the position regulation groove. The inner groove wall is moved to a position close to the groove opening, the end portion of the cross beam is brought into contact with the side wall of the stud, the repositioning spring pushes the insertion pin, and the plurality of the insertion pins are the plurality of the insertion holes. The locking block is located outside the insertion hole.

By the above method, it is possible to adopt a lock type mounting and fix it thoroughly before mounting, or it can be conveniently removed by an insertion type connection.

The keel structure of the present invention mounts the locking block inside the insertion hole by rotating the knob to rotate the adjustment block prior to mounting and then mounting the end of the cross beam to the side wall of the stud. It can be inserted and brought into contact with the inner wall of the stud, which can be thoroughly fixed as a lock-type mounting. The locking block can be located outside the insertion hole by inverting the knob to rotate the adjustment block and mounting the end of the cross beam to the side wall of the stud. This makes it convenient to remove as an insertable connection. For this reason, if you choose the mounting method by rotating the knob before mounting and choose the lock type mounting, you can fix it thoroughly, and if you choose the mounting by the insertion type connection, it will be convenient to remove, which makes it convenient for the keel. The connection method can be selected according to the connection demand of different parts.

It is a local sideways sectional view at the time of lock attachment of the keel structure of this invention. It is a locally enlarged view of FIG. It is a figure which shows the end of the cross beam corresponding to FIG. FIG. 3 is a locally enlarged cross-sectional view of FIG. It is a local sideways sectional view at the time of mounting by the insertion type connection of the keel structure of this invention. It is a figure which shows the cross beam end part with respect to FIG. FIG. 6 is a cross-sectional view of a locally enlarged view of FIG.

The technical means of the present invention will be further described below with reference to the drawings. The present invention is not limited to the following examples.

As shown in FIGS. 1 to 7, a closed-section skeleton keel structure including a stud 1 and a cross beam 2 having a closed-section rectangular tube structure, and a plurality of insertion holes 11 are provided on the side wall of the stud 1. A connecting base 3 is fixed in the end portion of the cross beam, and a plurality of pin sleeves 31 provided along the longitudinal direction of the cross beam 2 are provided in the connecting base 3, and inserted into the pin sleeve 31. The pin 4 is movably provided, the inner end of the pin sleeve 31 is closed, and both ends of the pin sleeve 31 are in contact with the inner end of the insertion pin 4 and the inner end of the pin sleeve 31, respectively. A repositioning spring 32 is provided, and a locking groove 41 whose depth direction is perpendicular to the longitudinal direction of the insertion pin 4 is formed on the rod wall approaching the outer end of the insertion pin 4, and the inside of the locking groove 41 is formed. Is movably provided with a locking block 42, and the inner end of the locking block 42 and the bottom of the locking groove 41 are connected by a first compression spring 43, and the locking block 42 is connected to the locking block 42. The portion extending from the locking groove 41 has an inclined structure, and the outer end surface of the locking block 42 has an inclined shape inclined toward the outer end of the insertion pin 4, and is formed on the rod wall of the insertion pin 4. The position-regulating groove 44 is formed, the position-regulating groove 44 has an open groove structure formed along the longitudinal direction of the insertion pin 4, and the inner end groove wall of the position-regulating groove 44 has a slope structure. The length of the groove mouth of the position restricting groove 44 is larger than the length of the groove bottom, and a cylindrical adjusting sleeve 33 provided along the longitudinal direction of the cross beam 2 is provided at the center position of the connecting base 3. An adjustment block 5 is movably provided in the adjustment sleeve 33, a plurality of adjustment grooves 51 are formed on the outer wall of the adjustment block 5, and the adjustment groove 51 is a circle of the adjustment block 5. It has an arcuate open groove structure formed in the circumferential direction, and the depth of the groove from the front end to the rear end of the adjustment groove 51 gradually decreases, and the adjustment sleeve 33 and the plurality of pin sleeves 31 are separated from each other. Each is connected by a control tube 35, the longitudinal direction of the control tube 35 is provided perpendicular to the longitudinal direction of the cross beam 2, and both ends of the control tube 35 pass through the adjustment sleeve 33 and the pin sleeve 31. The adjusting rod 6 is movably provided in the adjusting pipe 35, a sliding groove 36 is formed in the inner wall of the adjusting pipe 35, and the sliding groove 36 is formed in the rod wall of the adjusting rod 6. A sliding block 61 slidable is provided in the moving groove 36, and both ends of the adjusting rod 6 are slidable. The second compression spring 62 provided in contact with the outer end of the groove 36 and the sliding block 61 is exteriorized, and the second compression spring 62 is the sliding block 61 at the inner and outer ends of the adjusting rod 6. Is provided in contact with the bottom of the adjusting groove 51 and the inner groove wall of the position limiting groove 44, respectively.

The end portion of the cross beam 2 is provided so as to abut on the side wall of the stud 1, and the plurality of insertion pins 4 are pushed and moved by the repositioning spring 32 to be inserted into the plurality of insertion holes 11 and the adjustment thereof. When the outer end of the rod 6 abuts on the inner groove wall of the position restricting groove 44 at a position close to the groove opening, the locking block 42 is located outside the insertion hole 11. The knob 52 provided at the outer end of the adjustment block 5 rotates or inverts the adjustment block 5 to move the inner end of the adjustment rod 6 to the front end or the rear end of the adjustment groove 51. The outer end of the adjusting rod 6 can be moved to a position close to the groove opening in the inner groove wall of the position limiting groove 44, or to a position close to the groove bottom in the inner groove wall of the position limiting groove 44.

Further, the position of the inner groove wall of the position restricting groove 44 close to the groove bottom has a planar structure and is provided perpendicular to the longitudinal direction of the insertion pin 4. The depth of the central portion of the adjusting groove 51 is smaller than the depth of both ends, the depth of the adjusting groove 51 is gradually reduced from both ends to the central portion, and the position limiting groove 44 is formed between the bottom and the inner groove wall. A storage groove 45 is formed at the intersection by deepening the depth. The connection base 3 includes a connection sleeve 37 fixedly fitted to the inside of the cross beam 2, and the connection sleeve 37 includes the pin sleeve 31 and the adjustment sleeve 33 via a cross-shaped reinforcing rib 38. Connected, the adjusting sleeve 33 is located at the intersection of the reinforcing ribs 38, and the adjusting pipe 35 is located at the reinforcing rib 38. The length of the adjusting rod 6 is smaller than the inner diameter of the adjusting sleeve 33, and the groove mouth of the sliding groove 36 is located at the inner end of the adjusting pipe 35. An annular stop plate 34 is coaxially fixed to the inner wall of the outer end of the adjustment sleeve 33, and the stop plate 34 is provided with a support mark for aligning with the knob 52. A plurality of locking grooves 41 are formed on the rod wall of the insertion pin 4, and the plurality of locking grooves 41 are arranged along the circumferential direction of the insertion pin 4. The connecting sleeve 37, the reinforcing rib 38, the pin sleeve 31, the adjusting sleeve 33, and the adjusting pipe 35 have an integral structure. The outer end of the insertion pin 4 has a chamfered or circular angle.

In the keel structure of the present invention, the locking block 42 is attached by rotating the knob 52 to rotate the adjusting block 5 and attaching the end portion of the cross beam 2 to the side wall of the stud 1 before mounting. It can be inserted inside the insertion hole 11 and brought into contact with the inner wall of the stud 1, which can be thoroughly fixed as a lock type mounting. If the knob 52 is inverted to rotate the adjustment block 5 and the end portion of the cross beam 2 is attached to the side wall of the stud 1, the locking block 42 is placed outside the insertion hole 11. It can be positioned, which makes it convenient to remove as an insertable connection. Therefore, if you select the mounting method by rotating the knob 52 before mounting and select the lock type mounting, you can fix it thoroughly, and if you choose the mounting by the insertion type connection, the removal becomes convenient, and this makes the keel. The connection method can be selected according to the connection demand of different parts.

It is a mounting method of a closed cross-section skeleton keel structure, and includes a locking type mounting method and a mounting method by insertion connection.

In the lock mounting method, the knob 52 is rotated to rotate the adjustment block 5, the inner end of the adjustment rod 6 is moved to the front end of the adjustment groove 51, and the outer end of the adjustment rod 6 is restricted in position. The cross beam 2 is moved to a position close to the groove mouth on the inner groove wall of the groove 44, the cross beam 2 is brought into contact with the side wall of the stud 1, the repositioning spring 32 pushes the insertion pin 4, and the plurality of insertion pins 4 are moved. It is inserted into the plurality of insertion holes 11, and the locking block 42 is inserted inside the insertion holes 11 and abuts on the inner wall of the stud 1.

In the mounting method by the insertion connection, the knob 52 is inverted, the adjustment block 5 is rotated, the inner end of the adjustment rod 6 is moved to the rear end of the adjustment groove 51, and the outer end of the adjustment rod 6 is moved. The inner groove wall of the position restricting groove 44 is moved to a position close to the groove mouth, the end portion of the cross beam 2 is brought into contact with the side wall of the stud 1, and the repositioning spring 32 pushes and moves the insertion pin 4, and a plurality of. The insertion pin 4 is inserted into the plurality of insertion holes 11, and the locking block 42 is located outside the insertion holes 11.

The specific examples described herein will be described merely by taking the spirit of the present invention as an example. Technicians in the art to which the invention belongs may make various modifications or supplements to the specific embodiments described or substitute in similar manners, but deviate from the spirit of the invention or It does not exceed the scope defined in the attached claims.

The component names in the present application are given for the purpose of conveniently explaining and interpreting the essence of the present invention, and these names themselves are not limited and may be replaced with other terms.

1 Stud 11 Insertion hole 2 Cross beam 3 Connection base 31 Pin sleeve 32 Restoration spring 33 Adjustment sleeve 34 Stop plate 35 Adjustment pipe 36 Sliding groove 37 Connection sleeve 38 Reinforcing rib 4 Insertion pin 42 Locking groove 42 Locking block 43 First compression Spring 44 Position regulation groove 45 Storage groove 5 Adjustment block 51 Adjustment groove 52 Knob 6 Adjustment rod 61 Sliding block 62 Second compression spring

Claims (10)

It has a closed-section skeleton keel structure.
A stud and a cross beam having a closed cross-section rectangular tube structure are included, and the side wall of the stud is provided with a plurality of insertion holes.
A connecting base is fixed in the end of the cross beam,
The connection base is provided with a plurality of pin sleeves provided along the longitudinal direction of the cross beam.
An insertion pin is movably provided in the pin sleeve.
The inner end of the pin sleeve is closed.
A repositioning spring is provided in the pin sleeve so that both ends are in contact with the inner end of the insertion pin and the inner end of the pin sleeve, respectively.
A locking groove whose depth direction is perpendicular to the longitudinal direction of the insertion pin is formed on the bar wall approaching the outer end of the insertion pin.
A locking block is movably provided in the locking groove.
The inner end of the locking block and the bottom of the locking groove are connected by a first compression spring.
The portion of the locking block extending from the locking groove has an inclined structure.
The outer end surface of the locking block has a slope shape that is inclined toward the outer end of the insertion pin.
A position limiting groove is formed on the rod wall of the insertion pin.
The position limiting groove has an open groove structure formed along the longitudinal direction of the insertion pin.
The inner end groove wall of the position restricting groove has a slope structure.
The length of the groove mouth of the position-regulating groove is larger than the length of the groove bottom, and a cylindrical adjusting sleeve provided along the longitudinal direction of the cross beam is provided at the center position of the connection base.
An adjustment block is movably provided in the adjustment sleeve.
A plurality of adjustment grooves are formed on the outer wall of the adjustment block.
The adjusting groove has an arcuate opening groove structure formed in the circumferential direction of the adjusting block.
The depth of the groove from the front end to the rear end of the adjustment groove gradually decreases,
The adjusting sleeve and the plurality of pin sleeves are connected by an adjusting tube, respectively.
The longitudinal direction of the control pipe is provided perpendicular to the longitudinal direction of the cross beam.
Both ends of the adjusting tube are provided through the adjusting sleeve and the pin sleeve.
An adjusting rod is movably provided in the adjusting tube.
A sliding groove is formed on the inner wall of the control tube.
A sliding block slidably located in the sliding groove is provided on the rod wall of the adjusting rod.
The adjusting rod is externally provided with a second compression spring provided at both ends in contact with the outer end of the sliding groove and the sliding block.
The inner end and the outer end of the adjusting rod are provided so as to be in contact with the groove bottom of the adjusting groove and the inner groove wall of the position regulating groove, respectively, because the second compression spring pushes the sliding block.
The end of the cross beam is provided in contact with the side wall of the stud, the plurality of insertion pins are pushed and moved by the repositioning spring to be inserted into the plurality of insertion holes, and the outer end of the adjustment rod is the said. The locking block is located outside the insertion hole when it comes into contact with a position close to the groove opening on the inner groove wall of the position limiting groove. The knob provided at the outer end of the adjustment block rotates or inverts to rotate the adjustment block, and the inner end of the adjustment rod is moved to the front end or the rear end of the adjustment rod of the adjustment rod. The outer end can be moved to a position close to the groove opening on the inner groove wall of the position limiting groove, or to a position close to the groove bottom on the inner groove wall of the position limiting groove.
It features a closed cross-section skeleton keel structure. The position of the inner groove wall of the position-regulating groove close to the groove bottom has a planar structure and is provided perpendicular to the longitudinal direction of the insertion pin.
The closed cross-section skeleton keel structure according to claim 1. The depth of the adjustment groove is smaller than the depth of both ends, and the depth of the adjustment groove is gradually reduced from both ends to the middle part.
In the position-regulating groove, a storage groove is formed by deepening the depth at the intersection of the bottom and the inner groove wall.
The closed cross-section skeleton keel structure according to claim 2. The connecting base includes a connecting sleeve that is fixedly fitted to the inside of the cross beam.
The connecting sleeve is connected to the pin sleeve and the adjusting sleeve via a cross-shaped reinforcing rib.
The adjustment sleeve is located at the intersection of the reinforcing ribs.
The control tube is located on the reinforcing rib.
The closed cross-section skeleton keel structure according to claim 3. The length of the adjusting rod is smaller than the inner diameter of the adjusting sleeve, and the groove opening of the sliding groove is located at the inner end of the adjusting tube.
The closed cross-section skeleton keel structure according to claim 4. An annular stopper plate is coaxially fixed to the inner wall of the outer end of the adjustment sleeve.
The stop plate is provided with a support mark that aligns with the knob.
The closed cross-section skeleton keel structure according to claim 5. A plurality of locking grooves are formed on the bar wall of the insertion pin.
The plurality of locking grooves are arranged along the circumferential direction of the insertion pin.
The closed cross-section skeleton keel structure according to claim 6. The connecting sleeve, the reinforcing rib, the pin sleeve, the adjusting sleeve, and the adjusting tube have an integral structure.
The closed cross-section skeleton keel structure according to claim 7. The outer end of the insertion pin has a chamfered or circular angle.
The closed cross-section skeleton keel structure according to claim 8. The mounting method for a closed-section skeleton keel structure according to claim 9, which includes a locking mounting method and a mounting method by insertion connection.
In the lock mounting method, the knob is rotated to rotate the adjustment block, the inner end of the adjustment rod is moved to the front end of the adjustment groove, and the outer end of the adjustment rod is moved to the inner groove wall of the position regulation groove. The cross beam is brought into contact with the side wall of the stud, the repositioning spring pushes the insertion pin, and the plurality of insertion pins are inserted into the plurality of insertion holes. The stop block is inserted inside the insertion hole and abuts on the inner wall of the stud.
In the mounting method by the insertion connection, the knob is inverted to rotate the adjustment block, the inner end of the adjustment rod is moved to the rear end of the adjustment groove, and the outer end of the adjustment rod is the position regulation groove. The inner groove wall is moved to a position close to the groove opening, the end portion of the cross beam is brought into contact with the side wall of the stud, the repositioning spring pushes the insertion pin, and the plurality of the insertion pins are the plurality of the insertion holes. The locking block is located outside the insertion hole.
The mounting method is characterized by that.

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