CN112696039B

CN112696039B - Automatic health preserving of bulky concrete temperature difference control and insulation construction

Info

Publication number: CN112696039B
Application number: CN202110060120.0A
Authority: CN
Inventors: 赵佳康; 陈昊; 栗丰; 周建全; 华成涛; 张红颖; 闫志军
Original assignee: Qinhuangdao Municipal Construction Group Co ltd
Current assignee: Qinhuangdao Municipal Construction Group Co ltd
Priority date: 2021-01-18
Filing date: 2021-01-18
Publication date: 2022-03-01
Anticipated expiration: 2041-01-18
Also published as: CN112696039A

Abstract

The invention provides a temperature difference control automatic curing and heat-insulating structure for mass concrete, which relates to the technical field of concrete curing, solves the problems that the prior concrete building cannot be quickly and effectively covered in the practical application process, therefore, the method cannot be suitable for the maintenance operation of large concrete buildings, and cannot automatically monitor the temperature in the concrete and rapidly adjust the temperature, therefore, the problem that the temperature of the concrete building can not be kept constant in the curing process can not be effectively ensured, including a bearing mechanism, the bearing mechanism is provided with four parts, in the invention, the base and the support plate are effectively fixed through the self-locking elastic column, then, the support columns in the support mechanisms with different specifications can be selected according to actual use requirements, and the support columns are inserted into the inner positions of the sliding grooves formed in the top end of the base in the bearing mechanism through the inserting blocks fixedly connected with the bottom end faces of the support columns.

Description

Automatic health preserving of bulky concrete temperature difference control and insulation construction

Technical Field

The invention belongs to the technical field of concrete curing, and particularly relates to a large-volume concrete temperature difference control automatic curing and heat-insulating structure.

Background

Concrete curing is the artificial creation of certain humidity and temperature conditions that allow the concrete to be normal or accelerate its hardening and strength growth. Concrete is therefore able to harden and develop strength gradually as a result of the hydration of cement, which requires certain temperature and humidity conditions. If the surrounding environment does not have the condition, the concrete needs to be manually cured;

after the concrete is poured, large concrete buildings such as bridge piers need to be covered and wrapped by using supports and cotton cloth, and then hot air is poured into the concrete to keep the temperature inside the concrete constant, so that the aim of protecting the concrete bridge piers is fulfilled.

For example, application No.: the invention relates to a concrete curing and heat insulating device which comprises a curing plate, a polyurethane heat insulating layer arranged on one side of the curing plate and a heating device arranged between the curing plate and the polyurethane heat insulating layer, wherein the heating device comprises a heating cavity arranged on the curing plate, heating rollers arranged in the heating cavity, a jacking device used for enabling the heating rollers to be in close contact with the inner surface of the curing plate and a driving device used for driving the jacking device to realize left-right reciprocating motion, more than two heating rollers are arranged on the curing plate, and each heating roller is connected with the jacking device; the maintenance plate is heated by the heating roller, and the polyurethane heat-insulating material is used for heat insulation, so that the loss of temperature is effectively avoided, the heat insulation is effectively realized, the safety and the environmental protection are realized, no pollution is caused, a large amount of materials are saved, and the concrete pouring work can be performed at a lower temperature.

Based on the search of the above patent and the discovery of the equipment in the prior art, although the above equipment can perform the maintenance operation on the concrete when in use, the equipment cannot perform the fast and effective covering operation on the large-sized concrete building in the practical application process, and therefore cannot be adapted to the maintenance operation of the large-sized concrete building, and furthermore, the equipment cannot automatically monitor and quickly adjust the temperature inside the concrete, and therefore cannot effectively ensure that the temperature of the concrete building is kept constant during the maintenance process.

Disclosure of Invention

In order to solve the technical problems, the invention provides a large-volume concrete temperature difference control automatic curing and heat insulation structure, which is used for solving the problems that the existing practical application process cannot quickly and effectively cover a large-volume concrete building, so that the existing concrete temperature difference control automatic curing and heat insulation structure cannot be suitable for the curing operation of a large-size concrete building, and cannot automatically monitor the temperature inside concrete and quickly adjust the temperature, so that the temperature of the concrete building cannot be effectively kept constant in the curing process.

The invention relates to a purpose and an effect of a large-volume concrete temperature difference control automatic curing and heat-insulating structure, which are achieved by the following specific technical means:

the automatic temperature difference control curing and heat-insulating structure for the mass concrete comprises bearing mechanisms, supporting mechanisms and splicing mechanisms, wherein the bearing mechanisms are arranged at four positions, every two bearing mechanisms which are spliced with each other are a group, and the two groups of bearing mechanisms are respectively arranged at the front side and the rear side of the top end face of each heat-insulating mechanism; the supporting mechanisms are arranged at four positions, wherein every two supporting mechanisms form one group, the two groups of supporting mechanisms are respectively connected to the inner sides of the two groups of bearing mechanisms in a sliding manner, and the inner sides of the two groups of supporting mechanisms are respectively provided with a heat insulation mechanism; the splicing mechanisms are arranged at four positions, and the four splicing mechanisms are respectively screwed at the top ends of the four supporting mechanisms; the splicing mechanism further comprises a detector and a fixing bolt, the detector is inserted into a round hole formed in the center of the inside of the joint, and the fixing bolt is screwed at the front end of the joint.

Further, the heat preservation mechanism comprises a base, a ventilation groove, an air inlet pipe and an air outlet pipe, wherein the ventilation groove is formed in the top end of the base, and the air inlet pipe and the air outlet pipe are respectively installed at the rear side and the front side of the left end of the base;

further, the bearing mechanism comprises a base, a support plate and a self-locking elastic column, wherein circular holes are linearly formed in the inner part and the side surface of the base, a square groove is formed in the left end of the base, the support plate is fixedly connected to the right end face of the base, the self-locking elastic column is elastically connected to the right side of the top end of the support plate, and the two bases are respectively arranged at the front side and the rear side of the top end face of the base in an installation state;

furthermore, the supporting mechanism comprises a supporting column, an inserting block, two inner bolts and a screw head, wherein the inserting block is fixedly connected to the bottom end surface of the supporting column, a screw hole is formed in the inserting block, a through groove is formed in the supporting column, the inner bolts are provided with two positions, the two inner bolts are arranged in the through groove formed in the supporting column in an up-and-down array manner, the screw head is fixedly connected to the top end surface of the supporting column, and the supporting column is slidably connected in a sliding groove formed in the base through the inserting block in an installation state and is screwed in the sliding groove through a bolt;

furthermore, the heat insulation mechanism comprises two clamping plates and anti-slip strips, the two clamping plates are provided with the anti-slip strips with semi-cylindrical sections on the inner sides, and the outer side surfaces of the two clamping plates are rotatably connected with inner bolts;

the heat insulation mechanism further comprises heat insulation cotton and sliding blocks, the heat insulation cotton is clamped at the inner side positions of the two clamping plates, the sliding blocks are arranged at four positions, each two sliding blocks form one group, the two groups of sliding blocks are fixedly connected to the top end surfaces and the bottom end surfaces of the two clamping plates respectively, and the two clamping plates are connected in sliding grooves formed in the top end and the bottom end of the strut in a sliding mode through the sliding blocks in an installation state;

furthermore, splicing mechanism is including connecting and interior screw hole, the joint is the design of cruciform structure, and the inside of connecting is the hollow structure design to interior four ends of joint have all been seted up interior screw hole, the joint is twisted through interior screw hole and is connect the top position at the screw head.

Compared with the prior art, the invention has the following beneficial effects:

in the invention, the base and the support plate are effectively fixed by the self-locking elastic column, then the support columns in the support mechanisms with different specifications can be selected according to actual use requirements, the support columns are inserted into the inner positions of the sliding grooves formed in the top end of the base in the bearing mechanism through the insertion blocks fixedly connected with the bottom end surfaces of the support columns, the insertion blocks are screwed through the screw holes formed in the front end of the base by the bolts after the positions of the plurality of support columns are rapidly adjusted according to the actual use requirements, so as to achieve the purpose of fixing, on the other hand, when the support columns need to be transversely and longitudinally extended, the joints in the splicing mechanism are screwed with the screw heads through the inner screw holes, the screwing is completed, the double stable fixation can be carried out through the fixing bolts, and the temperature in the concrete can be detected in real time by the detector inserted into the joints, when the temperature is too low, the base in the heat insulation mechanism can be started to spray hot air through the ventilation groove to keep the temperature of the concrete constant, and heat insulation cotton can be added to the inner sides of the two clamping plates in the heat insulation mechanism to perform heat insulation operation on the concrete building.

Drawings

Fig. 1 is a left side view of the present invention.

Fig. 2 is a left side view of the present invention.

Fig. 3 is a schematic front view of the present invention.

Fig. 4 is a right side view of the present invention.

Fig. 5 is a right-view structural diagram of the present invention.

Fig. 6 is a schematic top view of the present invention.

Fig. 7 is a schematic axial view of the present invention.

Fig. 8 is an enlarged schematic view of the structure at a in fig. 1 according to the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a heat preservation mechanism; 101. a base; 102. a ventilation groove; 103. an air inlet pipe; 104. an air outlet pipe; 2. a carrying mechanism; 201. a base; 202. a support plate; 203. a self-locking elastic column; 3. a support mechanism; 301. a pillar; 302. inserting a block; 303. an inner bolt; 304. a screw head; 4. a thermal insulation mechanism; 401. a splint; 402. anti-slip strips; 403. heat preservation cotton; 404. a slider; 5. a splicing mechanism; 501. a joint; 502. an inner threaded hole; 503. a detector; 504. and (5) fixing the bolt.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 8:

the invention provides a temperature difference control automatic curing and heat-insulating structure for mass concrete, which comprises: the heat insulation device comprises bearing mechanisms 2, supporting mechanisms 3 and splicing mechanisms 5, wherein the bearing mechanisms 2 are arranged at four positions, each two bearing mechanisms 2 which are spliced with each other form a group, and the two groups of bearing mechanisms 2 are respectively arranged at the front side and the rear side of the top end face of the heat insulation mechanism 1; the supporting mechanisms 3 are provided with four positions, wherein every two supporting mechanisms 3 form one group, the two groups of supporting mechanisms 3 are respectively connected to the inner sides of the two groups of bearing mechanisms 2 in a sliding manner, and the inner sides of the two groups of supporting mechanisms 3 are respectively provided with a heat insulation mechanism 4; the splicing mechanisms 5 are arranged at four positions, and the four splicing mechanisms 5 are respectively screwed at the top ends of the four supporting mechanisms 3; the splicing mechanism 5 further includes a detector 503 and a fixing bolt 504, the detector 503 is inserted into a circular hole formed in the center of the inside of the connector 501, and the fixing bolt 504 is screwed to the front end of the connector 501.

Wherein, heat preservation mechanism 1 is including base 101, ventilative groove 102, intake pipe 103 and outlet duct 104, ventilative groove 102 has been seted up on the top of base 101, intake pipe 103 and outlet duct 104 are installed respectively in the left end rear side and the front side position of base 101, base 101 in the accessible starts heat preservation mechanism 1 when the temperature is low keeps the constancy of temperature of concrete through ventilative groove 102 blowout steam, and the accessible adds heat preservation cotton 403 to the inboard position of two splint 401 in the mechanism 4 that separates the temperature to the concrete building operation that keeps warm.

Wherein, bearing mechanism 2 is including base 201, extension board 202 and auto-lock bullet post 203, and the round hole has all been seted up to the inside and the side of base 201 that are the straight line, and the left end of base 201 has seted up the square groove, and extension board 202 fixed connection is in the right-hand member face position of base 201, and the top right side elastic connection of extension board 202 has auto-lock bullet post 203, and both sides position around the top end face of base 101 is installed respectively to two base 201 under the installation state.

Wherein, the supporting mechanism 3 includes a supporting column 301, an inserting block 302, an internal bolt 303 and a bolt head 304, the bottom end face of the supporting column 301 is fixedly connected with the inserting block 302, and the inside of the inserting block 302 is provided with a screw hole, the inside of the supporting column 301 is provided with a through groove, the internal bolt 303 is provided with two positions, and the two internal bolts 303 are arranged in the through groove arranged inside the supporting column 301 in an up-and-down array manner, the bolt head 304 is fixedly connected at the top end face position of the supporting column 301, the supporting column 301 is connected in the sliding groove arranged inside the base 201 through the inserting block 302 in a sliding manner in an installation state, and is screwed in the sliding groove through a bolt.

The heat insulation mechanism 4 comprises a clamping plate 401 and anti-slip strips 402, wherein the clamping plate 401 is provided with two positions, the anti-slip strips 402 with semi-cylindrical sections are mounted on the inner sides of the clamping plates 401 at the two positions, and the outer side surfaces of the clamping plates 401 at the two positions are rotatably connected with inner bolts 303.

Wherein, it is cotton 403 and slider 404 to separate the temperature mechanism 4 still including keeping warm, keeps warm cotton 403 and presss from both sides tightly in the inboard position of two splint 401, and slider 404 is equipped with everywhere altogether, and wherein every two slider 404 are a set of, and two sets of sliders 404 fixed connection respectively are in the top end face and the bottom end face position of two splint 401, and two splint 401 all pass through slider 404 sliding connection under the installation state in the spout that the inside top and the bottom of pillar 301 were seted up.

The splicing mechanism 5 includes a joint 501 and an inner screw hole 502, the joint 501 is designed in a cross structure, the inside of the joint 501 is designed in a hollow structure, the inner screw holes 502 are formed in four ends of the inside of the joint 501, and the joint 501 is screwed on the top end of the screw head 304 through the inner screw hole 502.

When in use: firstly, placing a base 101 in a heat insulation mechanism 1 at the periphery of a large concrete building, then placing bases 201 in two groups of bearing mechanisms 2 on the base 101, adjusting the rotation angle between every two adjacent bases 201 and support plates 202 according to actual requirements, effectively fixing the bases 201 and the support plates 202 through self-locking elastic columns 203, then selecting support columns 301 in supporting mechanisms 3 with different specifications according to actual use requirements, inserting the support columns 301 into sliding grooves formed in the top ends of the bases 201 in the bearing mechanisms 2 through insertion blocks 302 fixedly connected with the bottom end surfaces of the support columns 301, rapidly adjusting the positions of a plurality of support columns 301 according to actual use requirements, and then sequentially penetrating through screw holes formed in the front ends of the bases 201 through bolts to screw the insertion blocks 302 so as to achieve the purpose of fixing;

on the other hand, when the supporting column 301 needs to be extended transversely and longitudinally, the joint 501 in the splicing mechanism 5 can be screwed with the screw head 304 through the internal screw hole 502, the double stable fixation can be performed through the fixing bolt 504 after the screwing is completed, the temperature inside the concrete can be detected in real time through the inserting detector 503 into the joint 501, when the temperature is too low, the temperature of the concrete can be kept constant by starting the base 101 in the heat insulation mechanism 1 and spraying hot air through the air permeable groove 102, and the heat insulation operation can be performed on the concrete building by adding the heat insulation cotton 403 to the inner side positions of the two clamping plates 401 in the heat insulation mechanism 4.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. The utility model provides an automatic health preserving of bulky concrete temperature difference control and insulation construction which characterized in that: the heat insulation device comprises bearing mechanisms (2), supporting mechanisms (3) and splicing mechanisms (5), wherein the bearing mechanisms (2) are arranged at four positions, every two bearing mechanisms (2) which are spliced with each other are a group, and the two groups of bearing mechanisms (2) are respectively arranged at the front side and the rear side of the top end face of the heat insulation mechanism (1); the supporting mechanisms (3) are arranged at four positions, wherein every two supporting mechanisms (3) form one group, the two groups of supporting mechanisms (3) are respectively connected to the inner sides of the two groups of bearing mechanisms (2) in a sliding mode, and the inner sides of the two groups of supporting mechanisms (3) are respectively provided with a heat insulation mechanism (4); the splicing mechanisms (5) are arranged at four positions, and the four splicing mechanisms (5) are respectively screwed at the top end positions of the four supporting mechanisms (3); the splicing mechanism (5) further comprises a detector (503) and a fixing bolt (504), the detector (503) is inserted into the inner position of a circular hole formed in the center of the inner portion of the joint (501), the fixing bolt (504) is screwed to the front end of the joint (501), the bearing mechanism (2) comprises a base (201), a support plate (202) and a self-locking elastic column (203), the inner portion and the side surface of the base (201) are provided with the circular holes linearly, the left end of the base (201) is provided with a square groove, the supporting mechanism (3) comprises a support column (301), an insert block (302), an inner bolt (303) and a screw head (304), the bottom end surface of the support column (301) is fixedly connected with the insert block (302), the screw hole is formed in the insert block (302), a through groove is formed in the support column (301), and the inner bolt (303) is provided with two positions, the two inner bolts (303) are arranged in an up-down array in a through groove formed in the strut (301), the heat insulation mechanism (4) further comprises heat insulation cotton (403) and sliding blocks (404), the heat insulation cotton (403) is clamped at the inner side positions of the two clamping plates (401), the sliding blocks (404) are arranged at four positions, each two sliding blocks (404) are in one group, the two groups of sliding blocks (404) are fixedly connected to the top end surfaces and the bottom end surfaces of the two clamping plates (401), the splicing mechanism (5) comprises a connector (501) and inner screw holes (502), the connector (501) is designed in a cross structure, the interior of the connector (501) is designed in a hollow structure, the inner screw holes (502) are formed in the four ends of the interior of the connector (501), and the connector (501) is screwed at the top end position of the screw head (304) through the inner screw holes (502).

2. The bulk concrete temperature difference control automatic curing and heat-preserving structure as claimed in claim 1, wherein: the heat preservation mechanism (1) comprises a base (101), a ventilation groove (102), an air inlet pipe (103) and an air outlet pipe (104), the ventilation groove (102) is formed in the top end of the base (101), and the air inlet pipe (103) and the air outlet pipe (104) are respectively installed at the rear side and the front side of the left end of the base (101).

3. The bulk concrete temperature difference control automatic curing and heat-preserving structure as claimed in claim 1, wherein: the support plate (202) is fixedly connected to the right end face of the base (201), the top right side of the support plate (202) is elastically connected with a self-locking elastic column (203), and the two bases (201) are respectively installed on the front side and the rear side of the top end face of the base (101) in an installation state.

4. The bulk concrete temperature difference control automatic curing and heat-preserving structure as claimed in claim 1, wherein: the screw head (304) is fixedly connected to the top end face of the support column (301), and the support column (301) is connected in a sliding groove formed in the base (201) in a sliding mode through the inserting block (302) in the mounting state and is screwed in the sliding groove through the bolt.

5. The bulk concrete temperature difference control automatic curing and heat-preserving structure as claimed in claim 1, wherein: the heat insulation mechanism (4) comprises a clamping plate (401) and anti-slip strips (402), wherein the clamping plate (401) is provided with two positions, the anti-slip strips (402) with semi-cylindrical sections are arranged on the inner sides of the two clamping plates (401), and inner bolts (303) are rotatably connected to the outer side surfaces of the two clamping plates (401).

6. The bulk concrete temperature difference control automatic curing and heat-preserving structure as claimed in claim 5, wherein: in the installation state, the two clamping plates (401) are connected in sliding grooves formed in the top end and the bottom end of the interior of the strut (301) in a sliding mode through the sliding blocks (404).