CN113235839A - Lattice formula building roofing horizontal support structure - Google Patents

Abstract

The utility model belongs to the technical field of lattice formula building and specifically relates to a horizontal bearing structure of lattice formula building roofing is related to, including the backup pad group, the backup pad group is used for supporting the roofing, and the upside of backup pad group slides and has dry subassembly, and dry subassembly is used for absorbing the moisture between backup pad group and the roofing. The supporting plate group is connected with a driving assembly used for driving the drying assembly to slide, the edge of the supporting plate group is connected with an air drying assembly used for air drying the drying box, the supporting plate group is connected with a first weight measuring assembly, the air drying assembly is connected with a second weight measuring assembly, the first weight measuring assembly and the second weight measuring assembly are both used for detecting the weight change degree of the drying assembly, and the first weight measuring assembly and the second weight measuring assembly are both electrically connected with the driving assembly. Air-dry being connected with the position finding subassembly that is used for detecting dry subassembly position on the subassembly, the position finding subassembly respectively with drive assembly and air-dry subassembly electric connection. This application has the waterproof effect of improvement building roofing.

Description

Lattice formula building roofing horizontal support structure

Technical Field

The application relates to the field of lattice type buildings, in particular to a horizontal supporting structure of a lattice type building roof.

Background

The lattice type light building is a wall plate bearing system which is formed by using a reinforced concrete beam column lattice with a small section size as a framework and embedding an aerated silicate block (or other light material blocks with certain strength and apparent density lower than 600kg/m 3) which takes furnace slag and coal ash as main raw materials. Compared with a brick-concrete structure, the system has the advantages of light dead weight, good energy-saving effect, simplified construction and the like.

At present, chinese patent with publication number CN209040387U discloses a horizontal support of roofing, including the backup pad, be equipped with the link between two backup pads, the link includes first round steel, second round steel, first round steel and second round steel cross connection, and two backup pads are run through respectively with the both ends of second round steel in the both ends of first round steel, and the both ends of first round steel and the both ends of second round steel all are equipped with the fixing base, and the fixing base is connected with the backup pad, is connected through the nut between fixing base and first round steel, the second round steel.

With respect to the related art in the above, the inventors consider that: the horizontal support of the roof does not have a waterproof function, and the roof can be in a wet state for a long time in rainy days, so that the roof material is easy to mildew or leak water.

Disclosure of Invention

In order to improve the water-proof effects of building roof, this application provides a lattice formula building roof horizontal support structure.

The application provides a horizontal bearing structure of lattice formula building roofing adopts following technical scheme:

the utility model provides a horizontal bearing structure of lattice formula building roofing, including the backup pad group, the backup pad group is used for supporting the roofing, it has dry subassembly to slide on the backup pad group, dry subassembly is used for absorbing the moisture between backup pad group and the roofing, be connected with the drive assembly who is used for driving dry subassembly to slide on the backup pad group, the edge connection of backup pad group has the air-dry subassembly that is used for air-drying dry box, be connected with first check weighing subassembly on the backup pad group, air-dry and be connected with second check weighing subassembly on the subassembly, first check weighing subassembly and second check weighing subassembly all are used for detecting the weight change degree of dry subassembly, check weighing subassembly and drive assembly electric connection, air-dry and be connected with the position finding subassembly that is used for detecting dry subassembly position on the subassembly, the position finding subassembly respectively with drive assembly and air-dry subassembly electric connection.

By adopting the technical scheme, the supporting plate groups provide support for the roof, and in rainy days, the drying component absorbs moisture between the roof and the supporting plate groups, so that the drying degree of the roof and the supporting plate groups is improved. After a large amount of moisture were absorbed to dry subassembly, after first weight measuring subassembly detected dry subassembly's weight increase to a certain degree, first weight measuring subassembly sent the signal of telecommunication to drive assembly, and drive assembly drive dry subassembly slides towards air-dry subassembly, and the position finding subassembly detects dry subassembly arrival air-dry subassembly position back, and the position finding subassembly sends the signal of telecommunication to drive assembly, and drive assembly stop work, and dry subassembly stops to remove. The position finding subassembly sends the signal of telecommunication to air-drying the subassembly simultaneously, air-dries the subassembly and air-dries the drying assembly.

After the drying assembly is air-dried, when the weight that the second weight measuring assembly detected the drying assembly drops to a certain degree, the second weight measuring assembly sends the signal of telecommunication to drive assembly, and drive assembly drive drying assembly slides towards the supporting plate group for drying assembly dries supporting plate group once more, reaches drying assembly reuse's purpose. Above-mentioned technical scheme passes through the supporting plate group, dry subassembly, drive assembly, air-dries subassembly, position finding subassembly, first weight finding subassembly and the second weight finding subassembly mutually support, has improved the water-proof effects of building roofing.

Optionally, the supporting plate group includes locating plate, backup pad, and locating plate and backup pad all are the level setting, and the locating plate distributes along the horizontal direction has two, and the backup pad is located between two locating plates, wears to be equipped with the locating lever in the backup pad, and two locating plates are worn to locate by the locating lever, and the locating plate is fixed on the locating lever.

Through adopting above-mentioned technical scheme, mutually support through two locating plates and backup pad, provide the outrigger jointly to the roofing, the locating lever is with locating plate and backup pad reciprocal anchorage, has improved the steadiness of locating plate and backup pad.

Optionally, the drying assembly comprises a drying box and a drying agent, the drying box is of a porous structure, the drying agent is filled in the drying box, and one drying assembly is arranged on each positioning plate in a sliding mode.

Through adopting above-mentioned technical scheme, mutually support through drying box and drier, absorb the moisture between supporting plate group and the roofing, improved the water-proof effects of building roofing.

Optionally, the upper surface of the positioning plate is provided with a sliding groove, and the drying box slides in the sliding groove.

Through adopting above-mentioned technical scheme, dry box and the groove sliding fit that slides have improved the stability that dry box slided.

It is optional, drive assembly all is equipped with one on every locating plate, drive assembly and dry subassembly one-to-one set up, drive assembly includes drive screw, the drive block, drive unit, it has the drive groove to open on the inner wall in groove of sliding, drive screw is located the drive inslot and rotates and connect in the locating plate, drive block threaded connection is in drive screw, the drive block slides in the drive inslot, it has the spacing groove to open on the lateral wall of dry box, the vertical side laminating of drive block fits the inner wall in spacing groove, the top surface and the bottom surface of drive block all with spacing groove's inner wall between have the interval, drive unit is used for ordering about drive screw and rotates.

Through adopting above-mentioned technical scheme, when needs drive drying assembly slided, drive unit orders about drive screw and rotates, and drive screw drives the drive block and slides, and the drive block drives the dry box and slides. The top surface and the bottom surface of the driving block are provided with intervals with the inner wall of the limiting groove, so that the support of the driving block to the vertical direction of the drying box is reduced, the pressure sensitivity of the drying box to the first weight measuring component and the second weight measuring component is improved, and the accuracy of detecting the weight change of the drying component by the first weight measuring component and the second weight measuring component is improved.

Optionally, the first weight measuring assembly is arranged on each positioning plate, the first weight measuring assembly comprises a first pressing plate, a first elastic part and a first pressure sensor, the accommodating groove is formed in the bottom wall of the sliding groove, the first pressing plate slides in the accommodating groove along the vertical direction, a round corner is formed in one side, facing the air drying assembly, of the first pressing plate, the first elastic part is connected between the first pressing plate and the bottom wall of the accommodating groove, the first pressure sensor is placed in the accommodating groove and located below the first pressing plate, and the first pressure sensor is electrically connected to the driving assembly.

Through adopting above-mentioned technical scheme, the increase of weight behind the drier absorbed moisture, when the drying box pressed on first clamp plate, first clamp plate pressed on first pressure sensor, reflected the weight change of dry subassembly through first clamp plate to first pressure sensor's pressure change, reached the effect of the change degree of detection dry subassembly weight. Set up the chamfer on the first clamp plate, reduced the possibility of dry box during sliding with first clamp plate dun.

Optionally, the bottom wall of the accommodating groove is provided with an installation groove, and the first pressure sensor is placed in the installation groove.

Through adopting above-mentioned technical scheme, the mounting groove is spacing to first pressure sensor, has improved first pressure sensor's stability.

Optionally, the air-dry subassembly is equipped with two sets ofly and with the locating plate one-to-one, air-dry subassembly including air-dry box, fan, air-dry box fixed connection in the locating plate keep away from one side of backup pad, air-dry box open towards one side of locating plate has the intercommunication mouth, the intercommunication mouth communicates in the groove that slides, air-dry box keep away from one side of locating plate and open and have a plurality of air-dry holes, the fan is connected on the lateral wall of air-dry box.

Through adopting above-mentioned technical scheme, when needs air-dry to dry subassembly, the dry box of drive removes to air-dry in the box, and the fan is bloied in the air-dry box towards air-dry box, air-dries the drier for moisture on the drier volatilizees to the atmosphere through the air-dry hole in, has reached the air-dried effect to dry subassembly.

Optionally, the second weight measuring assembly is arranged in each air drying box, a detection groove used for containing the second weight measuring assembly is formed in the inner bottom wall of each air drying box, the second weight measuring assembly comprises a second pressing plate, a second elastic part and a second pressure sensor, the second weight measuring assembly is the same as the first weight measuring assembly in principle, a round corner is formed in one side, facing the supporting plate group, of the second pressing plate, the position measuring assembly is arranged in each air drying box, the position measuring assembly comprises a proximity switch, the proximity switch is connected to the bottom of each air drying box, an induction head of the proximity switch penetrates through the detection groove, the proximity switch is used for detecting the position of the second pressing plate, the proximity switch is respectively connected with a fan and a driving assembly in an electric connection mode.

Through adopting above-mentioned technical scheme, after in dry box removed air-dry box, the second clamp plate received dry box and moved down to its applied pressure, and when the second clamp plate was close to proximity switch, proximity switch sent the signal of telecommunication to drive assembly, and drive assembly stop work. Simultaneously proximity switch sends the signal of telecommunication to the fan, and the fan air-dries the drier, and second pressure sensor detects the weight of dry subassembly and falls to certain degree, and second pressure sensor sends the signal of telecommunication to drive assembly, and drive assembly drive drying box moves towards the direction of locating plate. The proximity switch improves the accuracy of the positioning of the drying box within the seasoning box.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the waterproof effect of the building roof is improved through the mutual matching of the supporting plate group, the drying assembly, the driving assembly, the air drying assembly, the position measuring assembly, the first weight measuring assembly and the second weight measuring assembly;

2. the driving assembly comprises a driving screw rod, a driving block and a driving element, and the effect of driving the drying box to slide is achieved;

3. the first weight measuring assembly comprises a first pressing plate, a first elastic piece and a first pressure sensor, and the effect of detecting the weight change degree of the drying assembly is achieved.

Drawings

Fig. 1 is a schematic structural view of a horizontal support structure for a lattice type building roof according to an embodiment of the present application.

Fig. 2 is a cross-sectional view of a positioning plate according to an embodiment of the present application, which is mainly used for embodying a drying assembly and a first weight measuring assembly.

Fig. 3 is a schematic structural diagram of a driving assembly according to an embodiment of the present application.

Fig. 4 is an enlarged view at a in fig. 2.

Fig. 5 is a sectional view of the seasoning box according to the embodiment of the present application, which is mainly used to embody the second weighing unit and the positioning unit.

Fig. 6 is a schematic structural diagram of a support plate according to an embodiment of the present application.

Fig. 7 is a schematic structural diagram of a positioning plate and an air drying box in the embodiment of the present application, which is mainly used for embodying a clamping groove.

Fig. 8 is a sectional view of another position of the positioning plate according to the embodiment of the present application.

Fig. 9 is an enlarged view of B in fig. 8, mainly for embodying the stopper groove.

Description of reference numerals: 1. a group of support plates; 11. positioning a plate; 111. a card slot; 112. a sliding groove; 113. accommodating grooves; 114. mounting grooves; 115. a drive slot; 12. a support plate; 121. clamping the strip; 13. positioning a rod; 14. positioning a nut; 2. a drying assembly; 21. drying the box; 211. a limiting groove; 22. a desiccant; 3. a first weight measuring assembly; 31. a first platen; 32. a first elastic member; 33. a first pressure sensor; 4. a drive assembly; 41. a drive screw; 42. a drive block; 43. a driver element; 431. a motor; 5. air-drying the assembly; 51. air-drying the box; 511. a communication port; 512. air drying the holes; 513. an installation port; 514. a detection tank; 52. a fan; 53. a baffle plate; 6. a positioning component; 61. a proximity switch; 7. a second weight measuring assembly; 71. a second platen; 72. a second elastic member; 73. a second pressure sensor.

Detailed Description

The present application is described in further detail below with reference to figures 1-9.

The embodiment of the application discloses horizontal supporting structure of lattice formula building roofing. Referring to fig. 1, a horizontal support structure for a lattice building roof includes a support plate group 1, and the support plate group 1 is used for supporting a roof. The supporting plate group 1 is connected with the drying component 2, and the drying component 2 absorbs moisture between the supporting plate group 1 and a roof, so that the waterproof effect of the roof is improved.

Referring to fig. 2 and 3, in order to recycle the drying component 2, a first weight measuring component 3 for detecting the weight change degree of the drying component 2 and a driving component 4 for driving the drying component 2 to slide are connected to the supporting plate set 1, and the first weight measuring component 3 is electrically connected to the driving component 4.

Referring to fig. 1, an airing assembly 5 is attached to the edge of the support plate set 1.

After drying assembly 2 absorbed a large amount of moisture, first check weighing subassembly 3 detected drying assembly 2's weight change to a certain extent, and first check weighing subassembly 3 sends the signal of telecommunication to drive assembly 4 this moment, and drive assembly 4 drive drying assembly 2 slides towards the direction of air-drying subassembly 5.

Referring to fig. 1 and 5, in order to improve the stability of the positioning of the drying module 2 close to the seasoning module 5, a positioning module 6 for detecting the position of the drying module 2 is connected to the seasoning module 5.

Referring to fig. 3 and 5, the positioning element 6 is electrically connected to the driving element 4 and the seasoning element 5, respectively.

After the drying assembly 2 slides to the designated position, the positioning assembly 6 sends an electric signal to the driving assembly 4, and the driving assembly 4 stops working, so that the drying assembly 2 stops moving. And meanwhile, the position measuring component 6 sends an electric signal to the air drying component 5, and the air drying component 5 air-dries the drying component 2.

Referring to fig. 1 and 5, a second weighing module 7 for detecting the degree of weight change of the drying module 2 is connected to the seasoning module 5.

After drying assembly 2 air-dries, second check weighing subassembly 7 detects that drying assembly 2 weight becomes light, and second check weighing subassembly 7 sends the signal of telecommunication to drive assembly 4, and drive assembly 4 drive drying box 21 slides towards the direction of supporting plate group 1, and drying assembly 2 returns initial position, continues to carry out the drying to supporting plate group 1 and roofing, has reached drying assembly 2 reuse's effect.

Referring to fig. 1, the supporting plate group 1 includes two positioning plates 11 and two supporting plates 12, the two positioning plates 11 and the two supporting plates 12 are both horizontally disposed, and the two positioning plates 11 are horizontally disposed, and the supporting plates 12 are located between the two positioning plates 11. Locating levers 13 are respectively arranged at two ends of the supporting plate 12 in the length direction in a penetrating mode, the locating levers 13 are horizontally arranged, the locating levers 13 are arranged in two locating plates 11 in a penetrating mode, two ends of each locating plate 11 penetrate out of the corresponding locating plate 11, and each locating nut 14 is in threaded connection with the corresponding locating plate 11. The positioning nut 14 abuts against the positioning plate 11, so that the positioning plate 11 is fixed on the positioning rod 13.

Two locating plates 11 and backup pad 12 cooperate jointly to provide the support for the roofing, have improved the stability of building roofing.

Referring to fig. 6 and 7, in order to improve the stability of the positioning plate 11 and the supporting plate 12, two sides of the supporting plate 12 are respectively and fixedly connected with a clamping strip 121, the positioning plate 11 is attached to the side surface of the supporting plate 12 and provided with a clamping groove 111, and the clamping strip 121 is clamped in the clamping groove 111. The clamping strip 121 is matched with the clamping groove 111 in an inserted manner, so that the positioning stability of the supporting plate 12 and the positioning plate 11 is improved.

Referring to fig. 1 and 2, one drying assembly 2 is slidably disposed on each positioning plate 11, and the drying assembly 2 includes a drying box 21 and a drying agent 22, where the drying box 21 has a porous structure. The drying agent 22 is silica gel, and the drying agent 22 is packed in the drying box 21. The drying agent 22 is used for absorbing moisture between the supporting plate group 1 and the roof, so that the waterproof effect of the roof is improved. The upper surface of the positioning plate 11 is provided with a sliding groove 112, the sliding groove 112 penetrates through the side surface of the positioning plate 11 far away from the support plate 12, and the drying box 21 slides in the sliding groove 112 along the horizontal direction. The sliding groove 112 provides a guide for the drying box 21, and improves the sliding stability of the drying box 21.

Referring to fig. 2 and 4, one first weight measuring assembly 3 is disposed on each positioning plate 11, and the first weight measuring assemblies 3 are disposed in one-to-one correspondence with the drying assemblies 2. The first weight measuring assembly 3 comprises a first pressing plate 31, a first elastic piece 32 and a first pressure sensor 33, a containing groove 113 is formed in the bottom wall of the sliding groove 112, the first pressing plate 31 vertically slides in the containing groove 113, and in order to reduce the possibility that the drying box 21 is blocked with the first pressing plate 31 in the sliding process, a fillet is formed at one side, facing the air drying assembly 5, of the first pressing plate 31. The first elastic members 32 are compression springs, two first elastic members 32 are arranged on the lower side of the first pressing plate 31, and the first elastic members 32 are fixedly connected to the first pressing plate 31 and the bottom wall of the accommodating groove 113 respectively.

Referring to fig. 4, the first pressure sensor 33 is located in the receiving groove 113 and below the first pressure plate 31, and in order to improve stability of the first pressure sensor 33, a mounting groove 114 is formed in a bottom wall of the receiving groove 113, the first pressure sensor 33 is placed in the mounting groove 114, and a top of the first pressure sensor 33 protrudes out of the mounting groove 114.

When the drying box 21 is pressed against the first pressing plate 31, the two first elastic members 32 apply an upward elastic force to the first pressing plate 31, so that the first pressing plate 31 provides support to the drying box 21. When the first pressing plate 31 moves downwards to abut against the first pressure sensor 33, a gap is formed between the bottom wall of the drying box 21 and the bottom wall of the sliding groove 112, and the degree of gravity change of the drying assembly 2 is reflected by the pressure applied thereto by the first pressing plate 31 detected by the first pressure sensor 33.

Referring to fig. 2 and 3, one driving assembly 4 is disposed on each positioning plate 11, and the driving assemblies 4 are disposed in one-to-one correspondence with the drying assemblies 2. The driving assembly 4 comprises a driving screw 41, a driving block 42 and a driving element 43.

Referring to fig. 1, the inner wall of the sliding groove 112 is provided with a driving groove 115, and the length direction of the driving groove 115 is directed to the support plate 12.

Referring to fig. 3, the driving screw 41 is positioned in the driving groove 115, and the driving screw 41 is rotatably coupled to the positioning plate 11. The driving unit 43 includes a motor 431, the motor 431 is fixed to the outer side of the positioning plate 11 by a bolt, an output shaft of the motor 431 penetrates through the driving groove 115 and is coaxially fixed to the driving screw 41, and an output shaft of the motor 431 is rotatably connected to the positioning plate 11. The first pressure sensor 33 is electrically connected to the motor 431.

Referring to fig. 3, the driving block 42 is screwed to the driving screw 41, the driving block 42 slides in the driving groove 115, and the driving block 42 is attached to the inner wall of the driving groove 115, thereby improving the stability of the driving block 42 when sliding.

When the drying box 21 needs to be driven to move, the motor 431 is started, the motor 431 drives the driving screw 41 to rotate, the driving screw 41 drives the driving block 42 to slide, and the driving block 42 drives the drying box 21 to slide.

Referring to fig. 8 and 9, the outer side wall of the drying box 21 close to the driving screw 41 is provided with a limiting groove 211, one side of the driving block 42 is inserted into the limiting groove 211, three vertical side surfaces of the driving block 42 close to the drying box 21 are all attached to the inner wall of the limiting groove 211, and the top surface and the bottom surface of the driving block 42 are all spaced from the inner wall of the limiting groove 211.

The driving block 42 and the drying box 21 have relative sliding spaces in the vertical direction, and the supporting force of the driving block 42 in the vertical direction applied to the drying box 21 is reduced, so that the pressure sensitivity of the drying box 21 to the first weight measuring assembly 3 and the second weight measuring assembly 7 is improved, and the accuracy of the weight change of the first weight measuring assembly 3 and the second weight measuring assembly 7 in the detection of the drying assembly 2 is improved.

Referring to fig. 1, the air-drying assembly 5 is fixedly connected to each positioning plate 11, the air-drying assembly 5 includes an air-drying box 51 and a fan 52, the air-drying box 51 is fixedly connected to one side of the positioning plate 11 away from the supporting plate 12, a communication opening 511 is formed in one side of the air-drying box 51 close to the positioning plate 11, the communication opening 511 is communicated with the inside of the air-drying box 51, and the communication opening 511 is communicated with the sliding groove 112. The side of the air drying box 51 far away from the positioning plate 11 is provided with a plurality of air drying holes 512. An installation opening 513 is formed in one side of the air drying box 51, the fan 52 is installed in the installation opening 513, and an air outlet of the fan 52 faces the interior of the air drying box 51.

Referring to fig. 1 and 2, when it is required to dry the drying assembly 2, the drying box 21 is moved into the drying box 51, and the top side of the drying box 21, the side facing the blower 52, and the side facing the drying holes 512 are all porous structures. The blower 52 blows air toward the drying box 21 to dry the drying agent 22, and moisture dried by the drying agent 22 is discharged to the atmosphere through the drying hole 512. In order to reduce the possibility of moisture evaporating into the slide groove 112, the side of the drying box 21 remote from the seasoning box 51 is closed.

Referring to fig. 7, to reduce the influence of the motor 431 on the external environment, the motor 431 is located inside the seasoning box 51, and the motor 431 is located on the side of the seasoning box 51 away from the blower 52. A baffle plate 53 is fixedly connected in the air drying box 51, and the side surface of the baffle plate 53 facing the fan 52 is flush with one side surface of the sliding groove 112. When the drying box 21 enters the seasoning box 51, the baffle 53 is used for guiding the drying box 21, and the stability of sliding of the drying box 21 in the seasoning box 51 is improved.

Referring to fig. 5, one second weighing module 7 is disposed in each seasoning box 51, and a detection groove 514 for accommodating the second weighing module 7 is formed in the inner bottom wall of each seasoning box 51. The second weight measuring assembly 7 includes a second pressure plate 71, a second elastic member 72, and a second pressure sensor 73.

Referring to fig. 4 and 5, the second weight measuring assembly 7 is arranged in the same manner as the first weight measuring assembly 3.

Referring to fig. 5 and 7, the second pressure sensor 73 is electrically connected to the motor 431. In order to reduce the possibility that the drying box 21 gets stuck with the second presser plate 71 when sliding, the side of the second presser plate 71 facing the positioning plate 11 is rounded.

Referring to fig. 5 and 7, one positioning assembly 6 is arranged in each seasoning box 51, each positioning assembly 6 includes a proximity switch 61, the proximity switch 61 is screwed to the bottom of the seasoning box 51, an induction head of the proximity switch 61 penetrates through the detection groove 514, the proximity switch 61 is used for detecting the position of the second pressing plate 71, and the proximity switch 61 is electrically connected with the motor 431 and the fan 52 respectively.

When the drying box 21 moves into the seasoning box 51, the drying box 21 is moved upward by the interference of the chamfer of the second pressing plate 71, so that the drying box 21 is pressed on the upper surface of the second pressing plate 71, and the second pressing plate 71 is driven to move downward. When the second pressing plate 71 abuts against the second pressure sensor 73, the proximity switch 61 senses the second pressing plate 71, the proximity switch 61 sends an electric signal to the motor 431, the motor 431 stops working, and the drying box 21 stops moving. At this time, there is a gap between the inner bottom wall of the drying box 21 and the seasoning box 51, which improves the pressure sensitivity of the second weighing module 7 to the drying box 21. At the same time, the proximity switch 61 sends an electric signal to the blower 52, and the blower 52 blows air toward the drying box 21 to dry the drying agent 22.

When the second pressure sensor 73 detects that the pressure of the second pressing plate 71 on the drying device is reduced to a set value, the drying device 2 is completely dried, at this time, the second pressure sensor 73 sends an electric signal to the motor 431, the motor 431 drives the driving screw 41 to rotate, the drying box 21 is driven to move towards the direction away from the drying box 51 through the linkage and matching of the driving screw 41, the driving block 42 and the drying box 21, after the drying box 21 is separated from the second pressing plate 71, the second pressing plate 71 moves upwards under the elastic force of the second elastic piece 72, and after the position measuring device 6 detects that the second pressing plate 71 is separated, the electric signal is sent to the fan 52, the fan 52 stops working, and the energy consumption of the fan 52 is saved.

When the drying box 21 returns to the position of the first pressing plate 31, the drying box 21 firstly collides with the chamfer of the first pressing plate 31, the drying box 21 moves upwards and presses the upper surface of the second pressing plate 71, and the drying box 21 continues to absorb water after returning to the initial position, so that the effect of recycling the drying agent 22 is achieved.

The implementation principle of the horizontal supporting structure of the lattice type building roof in the embodiment of the application is as follows: the desiccant 22 absorbs moisture between the support plate group 1 and the roof, and when the desiccant 22 is absorbed for a period of time and reaches saturation, the weight of the desiccant 22 increases, so that the weight of the drying box 21 on the first pressure plate 31 increases, and the pressure of the first pressure plate 31 on the first pressure sensor 33 increases. When the first pressure sensor 33 detects that the pressure applied thereto by the first pressure plate 31 has increased to a set value, the first pressure sensor 33 sends an electric signal to the motor 431. The motor 431 drives the driving screw 41 to rotate, the driving screw 41 drives the driving block 42 to slide, and the driving block 42 drives the drying box 21 to slide towards the direction of the seasoning box 51.

When the drying box 21 moves into the drying box 21, the drying box 21 presses on the upper surface of the second pressing plate 71, the second pressing plate 71 is driven to move downwards, and when the second pressing plate 71 abuts against the second pressure sensor 73, the proximity switch 61 senses the second pressing plate 71. At this time, the proximity switch 61 sends an electric signal to the motor 431, and the motor 431 stops operating, so that the drying box 21 stops moving. At the same time, the proximity switch 61 sends an electric signal to the blower 52, and the blower 52 blows air toward the drying box 21 to dry the drying agent 22.

When the second pressure sensor 73 detects that the pressure of the second pressure plate 71 to the drying assembly 2 is reduced to a set value, the drying assembly 2 is air-dried, at the moment, the second pressure sensor 73 sends an electric signal to the motor 431, the motor 431 drives the driving screw 41 to rotate, the drying box 21 is driven to move towards the direction far away from the air-drying box 51 through linkage matching of the driving screw 41, the driving block 42 and the drying box 21, the drying box 21 is made to return to the initial position, the effect of recycling the drying agent 22 is achieved, and the waterproof effect of a building roof is further improved.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a horizontal bearing structure of lattice formula building roofing which characterized in that: comprises a supporting plate group (1), the supporting plate group (1) is used for supporting a roof, a drying component (2) slides on the supporting plate group (1), the drying component (2) is used for absorbing moisture between the supporting plate group (1) and the roof, a driving component (4) used for driving the drying component (2) to slide is connected on the supporting plate group (1), the edge of the supporting plate group (1) is connected with an air-drying component (5) used for air-drying a drying box (21), the supporting plate group (1) is connected with a first weight measuring component (3), the air-drying component (5) is connected with a second weight measuring component (7), the first weight measuring component (3) and the second weight measuring component (7) are both used for detecting the weight change degree of the drying component (2), the first weight measuring component (3) and the second weight measuring component (7) are both electrically connected with the driving component (4), the air-drying component (5) is connected with a position measuring component (6) used for detecting the position of the drying component (2), the position measuring component (6) is respectively electrically connected with the driving component (4) and the air drying component (5).

2. The lattice building roofing horizontal support structure of claim 1, wherein: supporting plate group (1) includes locating plate (11), backup pad (12), and locating plate (11) and backup pad (12) all are the level setting, and locating plate (11) distribute along the horizontal direction has two, and backup pad (12) are located between two locating plates (11), wears to be equipped with locating lever (13) on backup pad (12), and two locating plates (11) are worn to locate in locating lever (13), and locating plate (11) are fixed on locating lever (13).

3. The lattice building roofing horizontal support structure of claim 2, wherein: the drying component (2) comprises a drying box (21) and a drying agent (22), the drying box (21) is of a porous structure, the drying agent (22) is filled in the drying box (21), and one drying component (2) is arranged on each positioning plate (11) in a sliding mode.

4. The lattice building roofing horizontal support structure of claim 3, wherein: the upper surface of the positioning plate (11) is provided with a sliding groove (112), and the drying box (21) slides in the sliding groove (112).

5. The lattice building roofing horizontal support structure of claim 4, wherein: drive assembly (4) all is equipped with one on every locating plate (11), drive assembly (4) and drying assembly (2) one-to-one set up, drive assembly (4) are including drive screw (41), driving block (42), drive unit (43), it has drive groove (115) to open on the inner wall in groove (112) that slides, drive screw (41) are located drive groove (115) and rotate and connect in locating plate (11), driving block (42) threaded connection is in drive screw (41), driving block (42) slide in drive groove (115), it has spacing groove (211) to open on the lateral wall of drying box (21), the vertical side laminating of driving block (42) fits the inner wall in spacing groove (211), the top surface and the bottom surface of driving block (42) all have the interval with between the inner wall of spacing groove (211), drive unit (43) are used for driving drive screw (41) and rotate.

6. The lattice building roofing horizontal support structure of claim 4, wherein: first check weighing subassembly (3) all is equipped with one on every locating plate (11), first check weighing subassembly (3) are including first clamp plate (31), first elastic component (32), first pressure sensor (33), holding tank (113) have been opened to the diapire in groove (112) slides, vertical slip in holding tank (113) is followed in first clamp plate (31), one side that first clamp plate (31) air-dried subassembly (5) is towards has the fillet, first elastic component (32) are connected between the diapire of first clamp plate (31) and holding tank (113), first pressure sensor (33) are placed in holding tank (113) and are located the below of first clamp plate (31), first pressure sensor (33) electric connection is in drive assembly (4).

7. The lattice building roofing horizontal support structure of claim 6, wherein: the bottom wall of the accommodating groove (113) is provided with an installing groove (114), and the first pressure sensor (33) is placed in the installing groove (114).

8. The lattice building roofing horizontal support structure of claim 6, wherein: air-dry subassembly (5) be equipped with two sets ofly and with locating plate (11) one-to-one, air-dry subassembly (5) including air-drying box (51), fan (52), air-dry box (51) fixed connection is in one side of locating plate (11) keeping away from backup pad (12), open one side of air-drying box (51) orientation locating plate (11) has intercommunication mouth (511), intercommunication mouth (511) communicate in glide groove (112), open one side of air-drying box (51) keeping away from locating plate (11) has a plurality of air-dry holes (512), fan (52) are connected on the lateral wall of air-drying box (51).

9. The lattice building roofing horizontal support structure of claim 8, wherein: the second weight measuring component (7) is arranged in each air drying box (51), a detecting groove (514) used for containing the second weight measuring component (7) is formed in the inner bottom wall of each air drying box (51), the second weight measuring component (7) comprises a second pressing plate (71), a second elastic component (72) and a second pressure sensor, the second weight measuring component (7) is identical to the first weight measuring component (3) in principle, a round corner is formed in one side, facing the supporting plate set (1), of each second pressing plate (71), the position measuring component (6) is arranged in each air drying box (51), the position measuring component (6) comprises a proximity switch (61), the proximity switch (61) is connected to the bottom of each air drying box (51), an induction head of the proximity switch (61) penetrates through the detecting groove (514), the proximity switch (61) is used for detecting the position of the second pressing plate (71), and the proximity switch (61) is respectively arranged in a position with the fan (52), The driving component (4) is electrically connected.

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