CN109537415B

CN109537415B - Gap positioning aid for gardening building

Info

Publication number: CN109537415B
Application number: CN201811497492.4A
Authority: CN
Inventors: 苏引江; 杨蕾; 刘柏辰; 袁亚彪
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-12-07
Filing date: 2018-12-07
Publication date: 2023-06-20
Anticipated expiration: 2038-12-07
Also published as: CN109537415A

Abstract

The invention discloses a gap positioning auxiliary device for gardening garden buildings, which comprises: the top of the supporting seat is provided with a containing groove, the inside of the supporting seat is provided with a containing cavity, the inside of the supporting seat is provided with at least one containing through hole, and the containing cavity of the supporting seat is internally provided with at least one containing pipe body corresponding to the at least one containing through hole; the at least one key mechanism comprises a first connecting rod, a gap positioning block and a clamping block, wherein the first connecting rod is telescopically arranged in the accommodating through hole, the gap positioning block is connected with one end of the first connecting rod and accommodated in the accommodating groove, and the clamping block is connected with the other end of the first connecting rod and accommodated in the accommodating cavity; the gap positioning block is rectangular, and the height of the gap positioning block is equal to or slightly smaller than the depth of the accommodating groove. Through the mode, the gap positioning auxiliary device for the gardening garden building disclosed by the invention can be clamped between the boards through the gap positioning blocks so as to accurately control the gap distance between the boards, so that the accuracy is high, and the user experience is greatly improved.

Description

Gap positioning aid for gardening building

Technical Field

The invention relates to the technical field of gardening garden buildings, in particular to a gap positioning auxiliary device for gardening garden buildings.

Background

In gardening garden buildings, some boards are often laid on the road surface, and for special cases, gaps between boards need to be controlled.

At present, the traditional mode mainly relies on the manual naked eye to control the gap distance between plank and the plank, and the accuracy is low, greatly reduced user's experience.

Disclosure of Invention

The invention mainly solves the technical problem of providing the gap positioning auxiliary device for the gardening architecture, which can be clamped between the boards through the gap positioning blocks so as to accurately control the gap distance between the boards, has high accuracy and greatly improves the experience of users.

In order to solve the technical problems, the invention adopts a technical scheme that: provided is a slit positioning assistor for gardening architecture, comprising: the top of the supporting seat is provided with a rectangular containing groove, wherein a containing cavity is arranged in the supporting seat, at least one containing through hole which enables the containing groove to be communicated with the containing cavity is arranged in the supporting seat, and at least one containing tube body corresponding to the at least one containing through hole is arranged in the containing cavity of the supporting seat; the at least one key mechanism comprises a first connecting rod, a gap positioning block and a clamping block, wherein the first connecting rod is telescopically arranged in the accommodating through hole, the gap positioning block is connected with one end of the first connecting rod and accommodated in the accommodating groove, and the clamping block is connected with the other end of the first connecting rod and accommodated in the accommodating cavity; the gap positioning block is rectangular, and the height of the gap positioning block is equal to or slightly smaller than the depth of the accommodating groove.

The clamping block is rectangular, the area of one side surface of the gap positioning block, which is close to the clamping block, is larger than the area of the section of the accommodating through hole, and the area of one side surface of the clamping block, which is close to the gap positioning block, is larger than the area of the section of the accommodating through hole.

The accommodating pipe body is provided with a first protruding block, a second protruding block, a third protruding block and a fourth protruding block at intervals along the length direction in one end, close to the gap positioning block, of the accommodating pipe body, and a first chute, a second chute, a third chute and a fourth chute are formed among the first protruding block, the second protruding block, the third protruding block and the fourth protruding block.

Wherein, at least one button mechanism still includes: one end of the second connecting rod is connected with the other side surface of the clamping block, which is far away from the gap positioning block, and one end of the second connecting rod, which is far away from the clamping block, is provided with a containing blind hole; the rotary driving block is cylindrical, one end of the rotary driving block is accommodated in the accommodating blind hole, the other end of the rotary driving block is accommodated in the accommodating pipe body, an annular protruding part is arranged on the outer wall of the middle of the rotary driving block, and a first sliding strip used for sliding in the first sliding groove, a second sliding strip used for sliding in the second sliding groove, a third sliding strip used for sliding in the third sliding groove and a fourth sliding strip used for sliding in the fourth sliding groove are arranged on the outer wall of the annular protruding part at intervals along the length direction of the rotary driving block; one end of the first spring is arranged in the accommodating tube body, and the other end of the first spring is connected with the other end of the rotary driving block; wherein, the one end that the block was put towards the card to first slider is equipped with first inclined plane, the one end that the block was put towards the card to the second slider is equipped with the second inclined plane, the one end that the block was put towards the card to the third slider is equipped with the third inclined plane, the one end that the block was put towards the card to the fourth slider is equipped with the fourth inclined plane, and the top interval that the one end was put the block was kept away from to the second connecting rod is provided with a plurality of strong points that are used for being connected with first inclined plane, the second inclined plane, third inclined plane and fourth inclined plane and are used for driving first slider to slide in first spout, the second slider slides in the second spout, the third slider slides in the third spout and the fourth slider slides in the fourth spout.

Wherein, the supporting point is in an equilateral triangle shape.

The first protruding block is provided with a first clamping opening for clamping the first sliding strip, the second sliding strip, the third sliding strip or the fourth sliding strip and a fifth inclined surface adjacent to the first clamping opening, the second protruding block is provided with a second clamping opening for clamping the first sliding strip, the second sliding strip, the third sliding strip or the fourth sliding strip and a sixth inclined surface adjacent to the second clamping opening, one end of the third protruding block, which is away from the gap positioning block, is provided with a third clamping opening for clamping the first sliding strip, the second sliding strip, the third sliding strip or the fourth sliding strip and a seventh inclined surface adjacent to the third clamping opening, and one end of the fourth protruding block, which is away from the gap positioning block, is provided with a fourth clamping opening for clamping the first sliding strip, the second sliding strip, the third sliding strip or the fourth sliding strip and an eighth inclined surface adjacent to the fourth clamping opening.

Wherein the first inclined surface, the second inclined surface, the third inclined surface and the fourth inclined surface are inclined in sequence towards the first direction, wherein the fifth inclined surface, the sixth inclined surface, the seventh inclined surface and the eighth inclined surface are inclined in sequence towards the second direction, the directions of the first inclined surface and the second inclined surface are opposite, one of the first direction and the second direction is clockwise, and the other of the first direction and the second direction is anticlockwise.

The lengths of the first sliding bar, the second sliding bar, the third sliding bar and the fourth sliding bar are larger than the length of the annular protruding portion.

The accommodating cavity is rectangular, and the depth of the inner hole of the accommodating tube body is smaller than the length of the first spring in a normal state.

Wherein, at least one button mechanism still includes: the second spring is accommodated in the accommodating cavity, the first connecting rod is arranged in the second spring in a penetrating mode, one end of the second spring is connected with the other side face, close to the gap positioning block, of the clamping block, and the other end of the second spring is connected with the inner wall of the accommodating cavity of the supporting seat.

The beneficial effects of the invention are as follows: unlike the prior art, the disclosed slot positioning assistor for gardening architecture comprises: the top of the supporting seat is provided with a containing groove, the inside of the supporting seat is provided with a containing cavity, the inside of the supporting seat is provided with at least one containing through hole, and the containing cavity of the supporting seat is internally provided with at least one containing pipe body corresponding to the at least one containing through hole; the at least one key mechanism comprises a first connecting rod, a gap positioning block and a clamping block, wherein the first connecting rod is telescopically arranged in the accommodating through hole, the gap positioning block is connected with one end of the first connecting rod and accommodated in the accommodating groove, and the clamping block is connected with the other end of the first connecting rod and accommodated in the accommodating cavity; the gap positioning block is rectangular, and the height of the gap positioning block is equal to or slightly smaller than the depth of the accommodating groove. Through the mode, the gap positioning auxiliary device for the gardening garden building disclosed by the invention can be clamped between the boards through the gap positioning blocks so as to accurately control the gap distance between the boards, so that the accuracy is high, and the user experience is greatly improved.

Drawings

FIG. 1 is a schematic perspective view of a slit positioning assistor for a gardening architecture according to the present invention;

FIG. 2 is a schematic view of the structure of a support base of the gap positioning aid for the gardening architecture of FIG. 1;

FIG. 3 is a schematic structural view of a key mechanism of the slot positioning aid for the gardening architecture of FIG. 1;

FIG. 4 is a schematic view of the partial enlarged structure of FIG. 3;

FIG. 5 is a schematic diagram of a rotary driving block of the key mechanism in FIG. 3;

FIG. 6 is a schematic view of the key mechanism of the slot positioning assist of FIG. 1 in combination with a receiving tube;

fig. 7 is a schematic structural view of a receiving tube of the support base in fig. 2.

Description of the embodiments

Referring to fig. 1 to 7, the gap positioning aid for gardening architecture comprises a supporting base 10 and at least one key mechanism 20.

The support base 10 has a rectangular shape. In the present embodiment, the top of the supporting seat 10 is provided with a rectangular receiving groove 101.

In the present embodiment, the support base 10 is provided with a receiving cavity 102 therein. Further, at least one receiving through hole 104 is formed in the support base 10 to communicate the receiving recess 101 with the receiving cavity 102.

It should be understood that the number of the at least one receiving through holes 104 is plural, and may be specific according to practical situations. Preferably, the at least one receiving through hole 104 includes eight receiving through holes. Further, seven of the eight accommodating through holes have equal inner diameters, and the other accommodating through hole has smaller inner diameter.

In the present embodiment, at least one accommodating tube 103 corresponding to the at least one accommodating through hole 104 is disposed in the accommodating cavity 102 of the supporting seat 10. It should be understood that at least one housing tube 103 is disposed on a side wall of the housing cavity 102 of the support base 10 away from the housing groove 101, and the housing through hole 104 is disposed on the other side wall of the housing cavity 102 of the support base 10 close to the housing groove 101. It should be noted that the accommodating through hole 104 and the accommodating tube 103 are in the same straight line.

In this embodiment, a first protruding block 1031, a second protruding block 1032, a third protruding block 1033, and a fourth protruding block 1034 are disposed at intervals along the length direction in one end of the housing tube 103 near the slit positioning block 201, wherein a first chute 1035, a second chute 1036, a third chute 1037, and a fourth chute 1038 are formed between the first protruding block 1031, the second protruding block 1032, the third protruding block 1033, and the fourth protruding block 1034. It should be understood that the first, second, third and fourth

sliding grooves

1035, 1036, 1037 and 1038 are provided along the length direction of the housing tube 103.

It is noted that the inner cavity of the housing tube 103 is circular, so that the first protruding block 1031, the second protruding block 1032, the third protruding block 1033 and the fourth protruding block 1034 are also arc-shaped, so that the inner sides of the first protruding block 1031, the second protruding block 1032, the third protruding block 1033 and the fourth protruding block 1034 also form a circular inner cavity.

It should be appreciated that the first, second, third and

fourth bump blocks

1031, 1032 are equal in length and width.

At least one key mechanism 20 is telescopically disposed in the accommodating recess 101. In this embodiment, the at least one key mechanism 20 includes a first link 203 telescopically disposed in the accommodating through hole 104, a slit positioning block 201 connected to one end of the first link 203 and accommodated in the accommodating groove 101, and a clamping block 202 connected to the other end of the first link 203 and accommodated in the accommodating cavity 102. It should be understood that the at least one key mechanism 20 includes a plurality of key mechanisms, and preferably, the at least one key mechanism 20 is in one-to-one correspondence with the at least one receiving through hole 104, i.e., the at least one key mechanism 20 includes eight key mechanisms.

Preferably, the slit positioning block 201 has a rectangular shape, and the height of the slit positioning block 201 is equal to or slightly smaller than the depth of the accommodating groove 101. That is, when the slit positioning block 201 is accommodated in the accommodating groove 101 (when the first link 203 is in the non-extended state), the slit positioning block 201 is not exposed outside the accommodating groove 101. It should be appreciated that, because the first connecting rod 203 is telescopically disposed in the accommodating through hole 104, when the first connecting rod 203 is lifted (i.e. in an extending state), the first connecting rod 203 drives the gap positioning block 201 to extend so that the gap positioning block 201 protrudes out of the accommodating groove 101, at this time, the gap positioning block 201 can be clamped between the boards, at this time, the width of the gap positioning block 201 is the gap spacing between the boards, so that the gap distance between the boards can be accurately controlled, the accuracy is high, and the user experience is greatly improved.

In this embodiment, the clamping block 202 is rectangular, the area of a side surface of the slit positioning block 201 near the clamping block 202 is larger than the area of the cross section of the accommodating through hole 104, and the area of a side surface of the clamping block 202 near the slit positioning block 201 is larger than the area of the cross section of the accommodating through hole 104. It should be appreciated that the catch 202 is primarily intended to limit the length of extension of the first link 203.

Further, in the present embodiment, the at least one key mechanism 20 further includes a second link 204, a rotation driving block 205, and a first spring 206.

One end of the second connecting rod 204 is connected with the other side surface of the clamping block 202 away from the gap positioning block 201, wherein a containing blind hole is formed in one end of the second connecting rod 204 away from the clamping block 202.

The rotary driving block 205 has a cylindrical shape, wherein one end of the rotary driving block 205 is accommodated in the accommodating blind hole, and the other end of the rotary driving block 205 is accommodated in the accommodating tube 103. It should be appreciated that one end of the rotary drive block 205 may simply be received within the receiving blind bore, or in other embodiments, one end of the rotary drive block 205 may be connected to an inner wall of the receiving blind bore by an elastic member such that one end of the rotary drive block 205 does not become dislodged from the receiving blind bore.

Preferably, the middle outer wall of the rotary driving block 205 is provided with a ring-shaped protrusion 2051, and the outer wall of the ring-shaped protrusion 2051 is provided with a first sliding bar 2052 for sliding in the first sliding groove 1035, a second sliding bar 2054 for sliding in the second sliding groove 1036, a third sliding bar 2056 for sliding in the third sliding groove 1037, and a fourth sliding bar for sliding in the fourth sliding groove 1038 at intervals along the length direction of the rotary driving block 205.

In this embodiment, the length of the first, second, third, or fourth

sliding bars

2052, 2054, 2056, or 2051 is greater than the length of the annular boss 2051. Preferably, the horizontal plane of the first sliding bar 2052, the second sliding bar 2054, the third sliding bar 2056, or the fourth sliding bar near the end of the housing tube 103 is the same as the horizontal plane of the annular protrusion 2051 near the end of the housing tube 103.

One end of the first spring 206 is provided in the housing tube 103, and the other end of the first spring 206 is connected to the other end of the rotation driving block 205. It should be understood that one end of the first spring 206 is received in the receiving tube 103 and fixed in the receiving tube 103, and the other end of the first spring 206 is fixedly connected with the other end of the rotary driving block 205.

It should be understood that the rotary drive block 205 and the second link 204 of the present embodiment may each be housed within the housing tube 103. And the receiving blind hole at one end of the second connecting rod 204 can receive one end of the rotary driving block 205, and one end of the second connecting rod 204 is clamped outside the annular protrusion 2051 of the rotary driving block 205. Further, when the receiving blind hole of the one end of the second link 204 receives the one end of the rotation driving block 205, the first sliding bar 2052, the second sliding bar 2054, the third sliding bar 2056 or the fourth sliding bar may be connected to the one end of the second link 204.

Preferably, the accommodating cavity 102 is rectangular, wherein the depth of the inner hole of the accommodating tube 103 is smaller than the length of the first spring 206 in a normal state, so that the first spring 206 applies a force to the rotary driving block 205, and the rotary driving block 205 pushes the clamping block 202 to move towards the direction approaching the gap positioning block 201.

In this embodiment, a first inclined surface 2053 is disposed at an end of the first sliding strip 2052 facing the clamping block 202, a second inclined surface 2055 is disposed at an end of the second sliding strip 2054 facing the clamping block 202, a third inclined surface is disposed at an end of the third sliding strip 2056 facing the clamping block 202, and a fourth inclined surface is disposed at an end of the fourth sliding strip facing the clamping block 202. Further, a plurality of support points 2041 for connecting the first inclined surface 2053, the second inclined surface 2055, the third inclined surface and the fourth inclined surface and driving the first sliding bar 2052 to slide in the first sliding groove 1035, the second sliding bar 2054 to slide in the second sliding groove 1036, the third sliding bar 2056 to slide in the third sliding groove 1037 and the fourth sliding bar to slide in the fourth sliding groove 1038 are provided at intervals on the top of the end of the second connecting rod 204 away from the clamping block 202. It should be appreciated that when the second link 204 moves toward the receiving tube 103, the plurality of support points 2041 of the second link 204 press the first inclined surface 2053, the second inclined surface 2055, the third inclined surface, and the fourth inclined surface to push the first runner 1035, the second slide bar 2054, the third slide bar 2056, and the fourth slide bar to move.

Preferably, the support points 2041 are in the shape of an equilateral triangle. Further, the first inclined surface 2053, the second inclined surface 2055, the third inclined surface, and the fourth inclined surface are inclined in this order in the first direction, wherein the first direction may be a counterclockwise direction or a clockwise direction. It should be appreciated that since the first, second, third, and fourth

inclined surfaces

2053, 2055 are inclined in order in the first direction, when the support point 2041 presses the first, second, third, and fourth

inclined surfaces

2053, 2055, 2041 applies a force to the first, second, third, and fourth

inclined surfaces

2053, 2055 in the second direction such that the first, second, third, and fourth

inclined surfaces

2053, 2055 have a potential to rotate in the second direction while they are still. Wherein the second direction is opposite to the first direction, and one of the first direction and the second direction is clockwise and the other of the first direction and the second direction is counterclockwise.

It is to be appreciated that when the first slide bar 2052 slides within the first slide groove 1035, the first slide groove 1035 defines the first slide bar 2052 not to rotate left and right, when the second slide bar 2054 slides within the second slide groove 1036, the second slide groove 1036 defines the second slide bar 2054 not to rotate left and right, when the third slide bar 2056 slides within the third slide groove 1037, the third slide groove 1037 defines the third slide bar 2056 not to rotate left and right, and when the fourth slide bar slides within the fourth slide groove 1038, the fourth slide groove 1038 defines the fourth slide bar not to rotate left and right.

In this embodiment, one end of the first protruding block 1031 away from the slit positioning block 201 is provided with a first clamping opening 10311 for clamping the first sliding bar 2052, the second sliding bar 2054, the third sliding bar 2056 or the fourth sliding bar, and a fifth inclined plane adjacent to the first clamping opening 10311, wherein the fifth inclined plane corresponds to the first inclined plane 2053, the second inclined plane 2055, the third inclined plane and the fourth inclined plane, i.e., the inclined direction of the fifth inclined plane is the same as the inclined directions of the first inclined plane 2053, the second inclined plane 2055, the third inclined plane and the fourth inclined plane.

In the present embodiment, one end of the second protruding block 1032 away from the slit positioning block 201 is provided with a second clamping opening 10321 for clamping the first sliding bar 2052, the second sliding bar 2054, the third sliding bar 2056 or the fourth sliding bar and a sixth inclined surface 10322 adjacent to the second clamping opening 10321, wherein the sixth inclined surface 10322 corresponds to the first inclined surface 2053, the second inclined surface 2055, the third inclined surface and the fourth inclined surface, i.e., the inclined direction of the sixth inclined surface 10322 is the same as the inclined directions of the first inclined surface 2053, the second inclined surface 2055, the third inclined surface and the fourth inclined surface.

In this embodiment, one end of the third protruding block 1033, which is far away from the slit positioning block 201, is provided with a third clamping opening 10331 for clamping the first sliding bar 2052, the second sliding bar 2054, the third sliding bar 2056 or the fourth sliding bar, and a seventh inclined plane adjacent to the third clamping opening 10331, wherein the seventh inclined plane corresponds to the first inclined plane 2053, the second inclined plane 2055, the third inclined plane and the fourth inclined plane, that is, the inclined direction of the seventh inclined plane is the same as the inclined directions of the first inclined plane 2053, the second inclined plane 2055, the third inclined plane and the fourth inclined plane.

In this embodiment, one end of the fourth protruding block 1034 away from the slit positioning block 201 is provided with a fourth clamping opening for clamping the first sliding bar 2052, the second sliding bar 2054, the third sliding bar 2056 or the fourth sliding bar and an eighth inclined plane adjacent to the fourth clamping opening, wherein the eighth inclined plane corresponds to the first inclined plane 2053, the second inclined plane 2055, the third inclined plane and the fourth inclined plane, i.e. the inclined direction of the eighth inclined plane is the same as the inclined directions of the first inclined plane 2053, the second inclined plane 2055, the third inclined plane and the fourth inclined plane.

That is, the fifth, sixth, seventh, and eighth inclined surfaces of the present embodiment are inclined in order in the second direction, and the first and fifth

inclined surfaces

2053 and 2053 are opposite in orientation.

Further, in some embodiments, the at least one key mechanism 20 further includes a second spring 207, wherein the second spring 207 is accommodated in the accommodating cavity, the first connecting rod 203 is disposed through the second spring 207, one end of the second spring 207 is connected to the other side surface of the clamping block 202 near the gap positioning block 201, and the other end of the second spring 207 is connected to the inner wall of the accommodating cavity 102 of the supporting seat 10. It should be appreciated that the second spring 207 is aligned with the receiving through hole 104, and the other end of the second spring 207 is disposed on a side wall of the receiving cavity 102 of the support base 10 near the slit positioning block 201, so as to apply pressure to the clamping block 202 through the second spring 207.

Notably, the rotary drive block 205 is rotatable such that the first slide bar 2052, the second slide bar 2054, the third slide bar 2056, and the fourth slide bar are each slidable within the first slide groove 1035, the second slide groove 1036, the third slide groove 1037, and the fourth slide groove 1038.

Further, the inner cavities formed by the first protruding block 1031, the second protruding block 1032, the third protruding block 1033 and the fourth protruding block 1034 are circular, and the inner diameters of the inner cavities formed by the first protruding block 1031, the second protruding block 1032, the third protruding block 1033 and the fourth protruding block 1034 are smaller than the inner diameter of the accommodating tube body 103.

Further, the outer walls of the first sliding strip 2052, the second sliding strip 2054, the third sliding strip 2056 and the fourth sliding strip are arc-shaped, the outer walls of the first sliding strip 2052, the second sliding strip 2054, the third sliding strip 2056 and the fourth sliding strip form a circular inner cavity, wherein the outer diameter of the circular inner cavity formed by the outer walls of the first sliding strip 2052, the second sliding strip 2054, the third sliding strip 2056 and the fourth sliding strip is smaller than the inner diameter of the accommodating tube 103, and the outer diameter of the circular inner cavity formed by the outer walls of the first sliding strip 2052, the second sliding strip 2054, the third sliding strip 2056 and the fourth sliding strip is larger than the inner diameter of the inner cavity formed by the first protruding block 1031, the second protruding block 1032, the third protruding block 1033 and the fourth protruding block 1034. In addition, the inner diameter of the inner cavity formed by the inner walls of the first, second, third and fourth sliding

bars

2052, 2054, 2056 is smaller than the inner diameter of the inner cavity formed by the first, second, third and

fourth boss

1031, 1032, 1033 and 1034.

Further, the outer diameter of the second link 204 is smaller than the inner diameter of the cavity formed by the first, second, third and

fourth boss

1031, 1032, 1033, 1034, and the outer diameter of the second link 204 is larger than the inner diameter of the cavity formed by the inner walls of the first, second, third and fourth sliding

bars

2052, 2054, 2056.

The specific working principle is as follows:

for example, taking the first sliding bar 2052 sliding in the third sliding groove 1037 as an example, when the user presses the slit positioning block 201 for the first time by hand, the slit positioning block 201 drives the clamping block 202 to move downward through the first connecting rod 203, and the clamping block 202 drives the second connecting rod 204 to press the rotation driving block 205, at this time, the supporting point 2041 of the second connecting rod 204 presses the first inclined surface 2053 to push the first sliding bar 2052 to slide downward in the third sliding groove 1037, and at this time, the first sliding bar 2052 is subjected to the force exerted by the supporting point 2041 and rotating toward the second direction.

When the first sliding bar 2052 slides down to the bottom of the second protruding block 1032, the first sliding bar 2052 is now disengaged from the third runner 1037, and the third runner 1037 can no longer restrict the first sliding bar 2052 from rotating. Since the first sliding bar 2052 is subjected to the force applied by the supporting point 2041 and rotating in the second direction, the rotary driving block 205 rotates in the lower Fang Chaodi direction of the second protruding block 1032 in the accommodating tube 103, so that the end of the first sliding bar 2052 provided with the first inclined surface 2053 is clamped in the second clamping opening 10321 of the second protruding block 1032, the user releases his hand, the first spring 206 cannot push the first sliding bar 2052 to move upwards, and the slit positioning block 201 is accommodated in the accommodating groove 101.

When the slit positioning block 201 is pressed for the second time, the slit positioning block 201 drives the clamping block 202 to move downward through the first connecting rod 203, and the clamping block 202 drives the second connecting rod 204 to press the rotation driving block 205, at this time, the supporting point 2041 of the second connecting rod 204 presses the first inclined surface 2053 to push the first sliding strip 2052 to slide downward under the first protruding block 1031 in the accommodating tube 103, and at this time, the first sliding strip 2052 is subjected to the force exerted by the supporting point 2041 and rotating towards the second direction.

When the first sliding strip 2052 slides down to the bottom of the second clamping opening 10321, the first sliding strip 2052 is separated from the second clamping opening 10321, and the second clamping opening 10321 cannot clamp the first sliding strip 2052 for rotation. Since the first sliding bar 2052 receives the force applied by the supporting point 2041 and rotating in the second direction, the rotation driving block 205 rotates in the two directions under Fang Chaodi of the second locking hole 10321 in the housing tube 103, so that the end of the first sliding bar 2052 provided with the first inclined surface 2053 rotates to the lower side of the sixth inclined surface 10322. At this time, the user releases his hand, since the sixth inclined surface 10322 and the first inclined surface 2053 are disposed in the same direction (i.e., in parallel), the first spring 206 pushes the first sliding bar 2052 to move into the second sliding groove 1036 and move upward, and the rotation driving block 205 can push the second link 204 to move upward, so that the slit positioning block 201 protrudes out of the accommodating groove 101, so as to be conveniently inserted between the slits between the boards.

In addition, as the number of the at least one key mechanism is multiple, the gap distance can be controlled by pressing the multiple key mechanisms according to actual needs. Preferably, the number of the slit positioning blocks 201 is eight, wherein the width of each of seven slit positioning blocks 201 is 2 mm, and the width of one slit positioning block 201 is 1 mm, so that control of the slit spacing between boards to be 1-15 mm can be achieved. If the gap between the boards is 1 mm, the gap spacing is controlled to be 1 mm by pressing the gap positioning block 201 with the width of 1 mm to protrude out of the accommodating groove 101 and clamping the gap positioning block 201 between the gaps; if the gap between the boards is required to be 2 mm, the gap spacing can be controlled to be 3 mm by pressing the gap positioning blocks 201 with the width of 1 mm and the gap positioning blocks 201 with the width of 2 mm adjacent to the gap positioning blocks to protrude out of the accommodating groove 101 and clamping the 2 gap positioning blocks 201 between the gaps.

In summary, the disclosed gap positioning assistor for gardening garden architecture comprises: the top of the supporting seat is provided with a containing groove, the inside of the supporting seat is provided with a containing cavity, the inside of the supporting seat is provided with at least one containing through hole, and the containing cavity of the supporting seat is internally provided with at least one containing pipe body corresponding to the at least one containing through hole; the at least one key mechanism comprises a first connecting rod, a gap positioning block and a clamping block, wherein the first connecting rod is telescopically arranged in the accommodating through hole, the gap positioning block is connected with one end of the first connecting rod and accommodated in the accommodating groove, and the clamping block is connected with the other end of the first connecting rod and accommodated in the accommodating cavity; the gap positioning block is rectangular, and the height of the gap positioning block is equal to or slightly smaller than the depth of the accommodating groove. Through the mode, the gap positioning auxiliary device for the gardening garden building disclosed by the invention can be clamped between the boards through the gap positioning blocks so as to accurately control the gap distance between the boards, so that the accuracy is high, and the user experience is greatly improved.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present invention.

Claims

1. A slit positioning aid for gardening architecture, comprising:

the support seat is provided with a rectangular accommodating groove at the top, wherein an accommodating cavity is arranged in the support seat, at least one accommodating through hole which enables the accommodating groove to be communicated with the accommodating cavity is arranged in the support seat, and at least one accommodating pipe body corresponding to the at least one accommodating through hole is arranged in the accommodating cavity of the support seat;

the at least one key mechanism comprises a first connecting rod, a gap positioning block and a clamping block, wherein the first connecting rod is telescopically arranged in the accommodating through hole, the gap positioning block is connected with one end of the first connecting rod and accommodated in the accommodating groove, and the clamping block is connected with the other end of the first connecting rod and accommodated in the accommodating cavity;

the gap positioning block is rectangular, and the height of the gap positioning block is equal to or slightly smaller than the depth of the accommodating groove;

the clamping block is rectangular, the area of one side surface of the gap positioning block, which is close to the clamping block, is larger than the area of the cross section of the accommodating through hole, and the area of one side surface of the clamping block, which is close to the gap positioning block, is larger than the area of the cross section of the accommodating through hole;

a first protruding block, a second protruding block, a third protruding block and a fourth protruding block are arranged at intervals along the length direction in one end of the accommodating tube body, which is close to the gap positioning block, wherein a first chute, a second chute, a third chute and a fourth chute are formed among the first protruding block, the second protruding block, the third protruding block and the fourth protruding block;

the at least one key mechanism further comprises:

one end of the second connecting rod is connected with the other side surface of the clamping block, which is far away from the gap positioning block, and one end of the second connecting rod, which is far away from the clamping block, is provided with a containing blind hole;

the rotary driving block is cylindrical, one end of the rotary driving block is accommodated in the accommodating blind hole, the other end of the rotary driving block is accommodated in the accommodating tube body, an annular protruding part is arranged on the outer wall of the middle of the rotary driving block, and a first sliding strip used for sliding in the first sliding groove, a second sliding strip used for sliding in the second sliding groove, a third sliding strip used for sliding in the third sliding groove and a fourth sliding strip used for sliding in the fourth sliding groove are arranged on the outer wall of the annular protruding part at intervals along the length direction of the rotary driving block;

one end of the first spring is arranged in the accommodating tube body, and the other end of the first spring is connected with the other end of the rotary driving block;

the first sliding bar faces one end of the clamping block, the second sliding bar faces the second inclined face, the third sliding bar faces one end of the clamping block, the fourth sliding bar faces one end of the clamping block, the top of one end of the second connecting rod, which is far away from the clamping block, is provided with a plurality of supporting points which are used for being connected with the first inclined face, the second inclined face, the third inclined face and the fourth inclined face and used for driving the first sliding bar to slide in the first sliding groove, the second sliding bar to slide in the second sliding groove, the third sliding bar to slide in the third sliding groove and the fourth sliding bar to slide in the fourth sliding groove at intervals.

2. The slot positioning assist of claim 1 wherein the support points are in the shape of equilateral triangles.

3. The slit positioning assistor according to claim 2, wherein one end of the first protruding block away from the slit positioning block is provided with a first clamping opening for clamping the first sliding bar, the second sliding bar, the third sliding bar or the fourth sliding bar and a fifth inclined surface adjacent to the first clamping opening, one end of the second protruding block away from the slit positioning block is provided with a second clamping opening for clamping the first sliding bar, the second sliding bar, the third sliding bar or the fourth sliding bar and a sixth inclined surface adjacent to the second clamping opening, one end of the third protruding block away from the slit positioning block is provided with a third clamping opening for clamping the first sliding bar, the second sliding bar, the third sliding bar or the fourth sliding bar and a seventh inclined surface adjacent to the third clamping opening, and one end of the fourth protruding block away from the slit positioning block is provided with a fourth inclined surface for clamping the first sliding bar, the third sliding bar or the fourth sliding bar and the fourth inclined surface adjacent to the fourth sliding bar.

4. The slot positioning assist of claim 3 wherein the first, second, third and fourth inclined surfaces are inclined in sequence in a first direction, wherein the fifth, sixth, seventh and eighth inclined surfaces are inclined in sequence in a second direction, and wherein the first and fifth inclined surfaces are oppositely oriented, one of the first and second directions being clockwise and the other of the first and second directions being counter-clockwise.

5. The slot positioning assist of claim 4 wherein the lengths of the first, second, third and fourth slider bars are greater than the length of the annular boss.

6. The slit positioning assist of claim 5, wherein the receiving cavity is rectangular in shape, wherein a depth of the inner hole of the receiving tube is smaller than a length of the first spring in a normal state.

7. The slot positioning assist of claim 6 wherein said at least one key mechanism further comprises:

the second spring is accommodated in the accommodating cavity, the first connecting rod penetrates through the second spring, one end of the second spring is connected with the other side face, close to the gap positioning block, of the clamping block, and the other end of the second spring is connected with the inner wall of the accommodating cavity of the supporting seat.