CN119373936A - An adjustable support device for vertical pipe of ground source heat pump system and its construction process - Google Patents

Abstract

The present invention discloses an adjustable support device for vertical pipes of a ground source heat pump system and a construction process thereof, and belongs to the technical field of vertical pipe support. The present invention arranges the pipeline laying mechanism horizontally, so as to facilitate the construction and assembly between the longitudinal pipes, reduce the difficulty of assembly, and pushes the first movable clamp through the fixing bolt to cooperate with the first fixed clamp to fix the bottom of the longitudinal pipe, and then the support frame can be unfolded in sequence through the cross telescopic arm, so that the unfolding distance of each support frame is the same, ensuring the equidistant positioning of the longitudinal pipe and improving the stability of the longitudinal pipe. At the same time, the unfolding of the cross telescopic arm can drive the slide rail to move, so that the ball rod drives the screw and nut to drive through the arc groove control shaft, so that the second movable clamp can be pushed to clamp the pipe, thereby meeting the multi-section equidistant fixation above the longitudinal pipe, avoiding the problem of increased difficulty of construction work caused by traditional welding and iron wire methods, thereby effectively improving construction efficiency.

Description

Adjustable supporting device for vertical pipe of ground source heat pump system and construction process of adjustable supporting device

Technical Field

The invention relates to the technical field of vertical pipe support, in particular to an adjustable support device for a vertical pipe of a ground source heat pump system and a construction process of the adjustable support device.

Background

In the construction process of the ground source heat pump system with the ground buried holes arranged below the building raft, the horizontal pipe of the ground source heat pump system always needs to climb for a certain height and then enter the inspection well, the construction of the section of vertical pipe is generally free from available building fixation, the vertical pipe has higher climbing height, fewer fixation points, difficult quality assurance, high construction difficulty and low fixation efficiency, and the surface of the vertical pipe needs to be cleaned after the installation of the vertical pipe, so that the invention provides the adjustable support device for the vertical pipe of the ground source heat pump system and the construction process thereof.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present invention has been developed in view of the above-described and/or existing standpipe supports.

Therefore, the invention aims to solve the technical problems that the vertical pipe has higher climbing height, fewer fixed points, difficult quality assurance, high construction difficulty and low fixing efficiency, and the surface of the vertical pipe needs to be cleaned after the vertical pipe is installed, so that the vertical pipe is very inconvenient.

In order to achieve the aim, the invention provides the technical scheme that the adjustable supporting device for the vertical pipe of the ground source heat pump system comprises a pipeline laying mechanism, wherein the pipeline laying mechanism is laid on one side of a basement structure;

the pipeline laying mechanism comprises a plurality of longitudinally arranged supporting frames, wherein supporting assemblies are arranged on two sides of one supporting frame, the front side and the rear side of the supporting frames are connected through a plurality of telescopic assemblies for adjusting the supporting frames, a clamping assembly is arranged above the telescopic assemblies and used for positioning the telescopic assemblies, and two ball rods are connected above the telescopic assemblies;

The top of the supporting frame of top is provided with auxiliary assembly, and the below is provided with two locating component in the supporting frame, locating component cooperates with corresponding first fixation clamp for to the below location of two rows of vertical pipes that set up side by side, remaining all be provided with two spacing subassemblies in the supporting frame, spacing subassembly cooperates with corresponding ball pole and second fixation clamp, is used for spacing to the top centre gripping of two rows of vertical pipes side by side, and the below of two rows of vertical pipes is provided with corresponding horizontal pipe.

The positioning assembly comprises a first movable clamp, wherein the first movable clamp is arranged in a lowest supporting frame, a first spring is fixedly connected between the first movable clamp and the lowest supporting frame, the first movable clamp corresponds to a first fixed clamp, the longitudinal pipe penetrates through the first movable clamp and the first fixed clamp, the first fixed clamp is fixedly connected in the lowest supporting frame, and a plurality of lifting hooks are fixedly connected above the highest supporting frame.

One side of the first movable clamp is provided with a fixed bolt, the fixed bolt is connected in a threaded sleeve in a threaded manner, and the threaded sleeve is arranged on the supporting frame;

The first sliding blocks are fixedly connected to the two sides of the first movable clamp, the first sliding blocks are slidably connected to the supporting frames, supporting legs are fixedly connected to one side of the lowest supporting frame, and a plurality of fixing rods are fixedly connected to the bottom of the lowest supporting frame.

As a further scheme of the invention, the support assembly comprises two adjusting telescopic rods, the bottom ends of the adjusting telescopic rods are fixedly connected with ground cones, the top ends of the adjusting telescopic rods are connected with connecting seats through universal joints, the two connecting seats are arranged on a connecting frame through bolts, and the connecting frame is fixedly connected to one side of the support frame.

As a further scheme of the invention, the auxiliary assembly comprises an outer frame, one side of the outer frame is fixedly connected with a pulley, a plurality of cleaning holes are formed in the outer frame, the longitudinal pipe penetrates through the cleaning holes, two side walls of the outer frame are fixedly connected with sliding strips, the sliding strips are slidably connected in a track, and the track is fixedly connected to one side of the supporting frame.

As a further scheme of the invention, the limiting assembly comprises a rotating shaft and two connecting rods, arc grooves are formed in the rotating shaft, and the ball rods are connected with the arc grooves in a sliding mode.

The invention further provides a scheme that two ends of the rotating shaft are fixedly connected with screw rods, the screw rods are rotatably arranged on the supporting frame through bearings, nuts are connected to the screw rods in a threaded mode, two nuts and two sides of the second movable clamp are fixedly connected with hinge blocks, the two hinge blocks are hinged with connecting rods through pin shafts, two ends of the second movable clamp are fixedly connected with second sliding blocks, the second sliding blocks are connected to the supporting frame in a sliding mode, the second movable clamp corresponds to the second fixed clamp, and the second fixed clamp is fixedly connected to the supporting frame.

As a further scheme of the invention, the telescopic assembly comprises a cross telescopic arm, two ends of the cross telescopic arm are hinged with two connecting blocks, the two connecting blocks are fixedly connected between two supporting frames, the other two ends of the cross telescopic arm are hinged with two sliding rails, the upper sliding rail is fixedly connected with a ball rod, the sliding rail is slidably connected with the sliding rail, the sliding rail is fixedly connected with the supporting frames, one end of the sliding rail is fixedly connected with a stop block, and the sliding rail is provided with a clamping opening.

As a further scheme of the invention, the clamping assembly comprises a clamping frame, the clamping frame is inserted into the clamping opening, and a telescopic rod and a second spring are fixedly connected between the clamping frame and the lower part of the upper sliding rail.

A construction process of an adjustable supporting device for a vertical pipe of a ground source heat pump system comprises the following steps:

S1, when a pipeline is paved, the pipeline paving mechanism is transversely arranged, a longitudinal pipe sequentially passes through a second movable clamp and a second fixed clamp, and passes through a space between a first movable clamp and a first fixed clamp, and then a fixed bolt is rotated to enable the fixed bolt to push the first movable clamp to enable the first movable clamp to be close to the first fixed clamp, so that the first movable clamp and the first fixed clamp and position the pipeline;

S2, sequentially expanding the supporting frames through the crossed telescopic arms, enabling the sliding rail to slide to the end parts of the guide rails, blocking the positions through the stop blocks, enabling the position of the clamping frame to correspond to the clamping opening, enabling the second spring to drive the clamping frame to reset, enabling the clamping frame to be clamped into the clamping opening, enabling the positions of the crossed telescopic arms to be fixed, and keeping the angle of each supporting frame;

S3, when the crossed telescopic arms are unfolded to drive the sliding rail to slide, the sliding rail is enabled to drive the ball rod to move, the ball rod controls the rotating shaft to rotate through the arc-shaped grooves, the rotating shaft drives the screw rod to rotate, the screw rod and the nut are in threaded transmission, the nut drives the connecting rod to rotate, the connecting rod is enabled to push the second movable clamp to move, the second movable clamp is enabled to be matched with the first fixing clamp to position the longitudinal pipe, the longitudinal pipe is enabled to meet the operation of each section of positioning support, then the connected longitudinal pipe is erected, the length of the telescopic rod is adjusted to be extended to the ground to be positioned, and then the horizontal pipe and the longitudinal pipe are connected.

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

1. According to the adjustable supporting device for the vertical pipe of the ground source heat pump system and the construction process thereof, the pipeline laying mechanism is transversely arranged, so that the longitudinal pipe can sequentially pass through the space between the second movable clamp and the second fixed clamp, construction and assembly are conveniently carried out between the longitudinal pipes, assembly difficulty is reduced, the first movable clamp is pushed by the fixing bolt to play a role in fixing the bottom of the longitudinal pipe in cooperation with the first fixed clamp, then the supporting frames can be sequentially unfolded through the crossed telescopic arms, the unfolding distance of each supporting frame is the same, equidistant positioning of the longitudinal pipe is ensured, stability of the longitudinal pipe is improved, meanwhile, the crossed telescopic arms can be unfolded to drive the sliding rail to move, the ball rod drives the screw rod and the nut to drive through the arc-shaped groove control rotating shaft, the second movable clamp is pushed to clamp the pipeline, therefore, the problem that the equal distance above the longitudinal pipe is fixed can be met, and the construction operation difficulty is increased due to the traditional welding and iron wire mode is avoided, and the construction efficiency can be effectively improved;

2. According to the adjustable supporting device for the vertical pipe of the ground source heat pump system and the construction process thereof, the supporting frames are connected through the cross telescopic arms, so that the supporting frames can be connected together, and the supporting frames can be folded through the retractility of the cross telescopic arms, so that the supporting frames can be folded together, the size can be greatly reduced to meet the requirement of convenient carrying, the supporting frames can be erected through the cross telescopic arms, the supporting frames can be stably erected on the longitudinal pipe, and meanwhile, the fixed points of the longitudinal pipe are increased for the expanded supporting frames, so that the device can be used without on-site construction and can be expanded, the construction operation is simple and convenient, and the construction progress can be further accelerated;

3. According to the adjustable supporting device for the vertical pipe of the ground source heat pump system and the construction process thereof, after the bottom of the longitudinal pipe is positioned through the positioning component, the supporting frames can be unfolded one by one through the crossed telescopic arms, the unfolded supporting frames enable the ball rod to be matched with the limiting component to clamp the longitudinal pipe in a multi-section mode, so that stability of the longitudinal pipe can be kept, paving quality of the longitudinal pipe is improved, the other end of the adjustable supporting device is supported through the moving wheel, labor-saving operation can be assisted for constructors, meanwhile, the outer frame moves along the supporting frames, the cleaning holes slide along the surface of the longitudinal pipe, the cleaning holes can clean the longitudinal pipe, cleaning operation can be completed in the process of assembling the longitudinal pipe, and cleaning cotton can be filled in the cleaning holes to clean;

4. according to the adjustable supporting device for the vertical pipe of the ground source heat pump system and the construction process of the adjustable supporting device, when the length of the longitudinal pipe to be supported is long, supporting frames and telescopic components with different numbers can be selected and customized for use, so that the adjustable supporting device can be suitable for supporting the longitudinal pipes with different lengths.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

Fig. 1 is a schematic diagram of a structure in which a pipe laying mechanism is laid in a basement in a construction process of an adjustable supporting device for a vertical pipe of a ground source heat pump system according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of an adjustable support device for a vertical pipe of a ground source heat pump system and a structure of a horizontal pipe arranged in a basement in a construction process thereof according to an embodiment of the present invention.

Fig. 3 is a schematic structural view of an adjustable support device for a vertical tube of a ground source heat pump system and a connection between a horizontal tube and a vertical tube in a construction process thereof according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of an adjustable supporting device for a vertical tube of a ground source heat pump system and a connection between a supporting frame and a supporting component in a construction process thereof according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an adjustable supporting device for a vertical tube of a ground source heat pump system and a positioning assembly in a construction process thereof according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of an adjustable supporting device for a vertical tube of a ground source heat pump system and a connection between a telescopic assembly and a supporting frame in a construction process thereof according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of an adjustable supporting device for a vertical tube of a ground source heat pump system and a connection between a supporting frame and a limiting component in a construction process thereof according to an embodiment of the present invention.

Fig. 8 is a schematic structural diagram of an adjustable support device for a vertical tube of a ground source heat pump system and a support assembly in a construction process thereof according to an embodiment of the present invention.

Fig. 9 is a schematic structural diagram of an adjustable supporting device for a vertical tube of a ground source heat pump system and a connection between a supporting frame and an auxiliary component in a construction process thereof according to an embodiment of the present invention.

Fig. 10 is a schematic diagram of a structure of an adjustable support device for a vertical tube of a ground source heat pump system and a support frame in a construction process thereof according to an embodiment of the present invention.

Fig. 11 is a schematic structural view of an adjustable supporting device for a vertical tube of a ground source heat pump system and an auxiliary assembly in a construction process thereof according to an embodiment of the present invention.

Fig. 12 is a schematic diagram of a three-dimensional structure of an adjustable supporting device for a vertical tube of a ground source heat pump system and a limiting assembly in a construction process thereof according to an embodiment of the invention.

Fig. 13 is a schematic view of a three-dimensional structure of a cross telescopic arm in an adjustable support device for a vertical tube of a ground source heat pump system and a construction process thereof according to an embodiment of the present invention.

Fig. 14 is an enlarged schematic structural view of a vertical tube-used adjustable support device of a ground source heat pump system and a construction process thereof in fig. 13 according to an embodiment of the present invention.

100, Basement structure, 200, pipe laying mechanism, 201, horizontal pipe, 202, longitudinal pipe, 203, supporting component, 2031, adjusting telescopic rod, 2032, ground cone, 2033, universal joint, 2034, connecting frame, 2035, connecting seat, 204, supporting frame, 205, telescopic component, 2051, cross telescopic arm, 2052, sliding rail, 2053, guide rail, 2054, stop, 2055, connecting block, 2056, clamping opening, 206, positioning component, 2061, first movable clamp, 2062, first spring, 2063, fixing bolt, 2064, threaded sleeve, 2065, first sliding block, 207, auxiliary component, 2071, outer frame, 2072, sliding strip, 2073, pulley, 2074, track, 2075, cleaning hole, 208, limiting component, 2081, rotating shaft, 2082, arc groove, 2083, screw, 2084, nut, 2085, connecting rod, 2086, hinge block, 2087, second movable clamp, 8, second sliding block, 209, clamping position component, clamping position, 2064, threaded sleeve, 2065, first sliding block, 207, auxiliary component, 2071, outer frame, 2072, sliding block, sliding rail, auxiliary component, 2071, elastic component, elastic rod, 2082, 2092, elastic rod, 2093, 2091, and supporting rod.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

In the following detailed description of the embodiments of the present invention, the cross-sectional view of the device structure is not partially enlarged to a general scale for the convenience of description, and the schematic is merely an example, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

Further still, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic may be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

As shown in fig. 1 to 10 and fig. 12 to 14, the present invention provides a technical solution that an adjustable support device for a vertical pipe of a ground source heat pump system includes a pipe laying mechanism 200, the pipe laying mechanism 200 being laid on one side of a basement structure 100;

The pipe laying mechanism 200 comprises a plurality of supporting frames 204 which are longitudinally arranged, wherein supporting assemblies 203 are arranged on two sides of one supporting frame 204, each supporting assembly 203 comprises two adjusting telescopic rods 2031, the bottom ends of the adjusting telescopic rods 2031 are fixedly connected with ground cones 2032, the ground cones 2032 can smoothly finish burying operation, meanwhile, the adjustable telescopic rods 2031 have telescopic characteristics, the adjustable telescopic rods 2031 can extend to length, the ground cones 2032 can smoothly contact the ground, the adjustable telescopic rods 2031 can further steer through universal joints 2033, thus the supporting angle can be adjusted, stable supporting of the supporting frame 204 can be met, the top ends of the adjusting telescopic rods 2031 are connected with connecting seats 2035 through the universal joints 2033, the angle of the adjusting telescopic rods 2031 can be adjusted, so that different supporting angles can be met, the supporting stability of the supporting frame 204 is ensured, the two connecting seats 2035 are installed on a connecting frame 2034 through bolts, the connecting frame 2034 is fixedly connected to one side of the supporting frame 204, the front side and the rear side of the supporting frames 204 are connected through a plurality of telescopic components 205 for adjusting the supporting frame 204, the telescopic components 205 comprise cross telescopic arms 2051, the cross telescopic arms 2051 have the telescopic characteristic, the supporting frame 204 can be smoothly unfolded, meanwhile, the cross telescopic arms 2051 are connected with the supporting frame 204, thereby the stable maintenance of the supporting frame 204 can be realized, the two ends of the cross telescopic arms 2051 are hinged with two connecting blocks 2055, the two connecting blocks 2055 are fixedly connected between the two supporting frames 204, the other two ends of the cross telescopic arms 2051 are hinged with two sliding rails 2052, the upper sliding rails 2052 are fixedly connected with the ball rods 211, the sliding rails 2052 are slidably connected on the sliding rails 2053, the sliding rails 2052 can be guided by the sliding rails 2053, the sliding rails 2052 can keep the stable expansion of the cross telescopic arms 2051, the sliding rails 2053 are fixedly connected on the supporting frame 204, one end of the guide rail 2053 is fixedly connected with a stop block 2054, the position of the guide rail 2052 can be blocked by the stop block 2054, the guide rail 2052 is prevented from falling out of the guide rail 2053, a clamping opening 2056 is formed in the guide rail 2053, a clamping assembly 209 is arranged above the telescopic assembly 205, the clamping assembly 209 comprises a clamping frame 2091, the clamping frame 2091 is inserted into the clamping opening 2056, a telescopic rod 2093 and a second spring 2092 are fixedly connected between the clamping frame 2091 and the lower part of the upper guide rail 2052, the clamping frame 2091 is driven to reset upwards by the second spring 2092, the clamping frame 2091 is clamped into the clamping opening 2056, the cross telescopic arm 2051 can be fixed, the cross telescopic arm 2051 smoothly maintains the height of the support frame 204, and is used for positioning the telescopic assembly 205, and the two ball rods 211 are connected above the telescopic assembly 205;

An auxiliary component 207 is arranged above the uppermost supporting frame 204, two positioning components 206 are arranged in the lowermost supporting frame 204, the positioning components 206 comprise a first movable clamp 2061, a first fixed clamp 214, The second movable clamp 2087 and the second fixed clamp 210 are respectively provided with a plurality of embedded surfaces matched with the outer diameter of the longitudinal pipe 202, so that the coating area of the longitudinal pipe 202 can be increased, the fixing stability of the longitudinal pipe 202 can be improved, the first movable clamp 2061 is arranged in the lowest supporting frame 204, a first spring 2062 is fixedly connected between the first movable clamp 2061 and the lowest supporting frame 204, the position of the first movable clamp 2061 can be kept by the first spring 2062, the first movable clamp 2061 is prevented from moving, the operation of assembling the longitudinal pipe 202 is convenient, the first movable clamp 2061 corresponds to the first fixed clamp 214, the longitudinal pipe 202 passes through the first movable clamp 2061 and the first fixed clamp 214, the first fixed clamp 214 is fixedly connected in the lowest supporting frame 204, a plurality of hanging hooks 213 are fixedly connected above the highest supporting frame 204, the operation of hanging the device by the hanging hooks 213 through the hanging devices, thereby facilitating the erection of the longitudinal tube 202, one side of the first movable clamp 2061 is provided with a fixing bolt 2063, the fixing bolt 2063 is in threaded connection with a threaded sleeve 2064, the fixing bolt 2063 is in transmission with the threaded sleeve 2064, the first movable clamp 2061 is pushed to fix the longitudinal tube 202 on the first fixing clamp 214, the bottom of the longitudinal tube 202 can be positioned in advance, the threaded sleeve 2064 is arranged on the supporting frame 204, both sides of the first movable clamp 2061 are fixedly connected with first sliding blocks 2065, the first sliding blocks 2065 slide on the supporting frame 204 through the first sliding blocks 2065, thereby enabling the first movable clamp 2061 to slide stably, the first sliding blocks 2065 slide on the supporting frame 204, one side of the lowest supporting frame 204 is fixedly connected with supporting legs 212, the supporting legs 212 can play a supporting role on the supporting frame 204 which is transversely arranged, the bottom of the lowest supporting frame 204 is fixedly connected with a plurality of fixing rods, the positioning assembly 206 is matched with the corresponding first fixing clamps 214, for positioning the lower parts of two rows of longitudinal pipes 202 arranged side by side, two limiting assemblies 208 are arranged in the rest of supporting frames 204, each limiting assembly 208 comprises a rotating shaft 2081 and two connecting rods 2085, each rotating shaft 2081 is provided with an arc-shaped groove 2082, a ball rod 211 is in sliding connection with each arc-shaped groove 2082, when the ball rod 211 moves, the ball rod 211 can control the rotating shaft 2081 to rotate through the arc surface of each arc-shaped groove 2082, so that a screw 2083 and a nut 2084 can be driven to carry out threaded transmission, two ends of each rotating shaft 2081 are fixedly connected with screws 2083, the screws 2083 are rotatably arranged on the supporting frames 204 through bearings, the nuts 2084 are in threaded connection with the screws 2084, the nuts 2084 can drive the connecting rods 2085 to turn through the threaded transmission of the screws 2084, the connecting rods 2085 can push the second movable clamps 2087 to move, the second movable clamps 2087 are matched with the second fixed clamps 210 to smoothly clamp and position the longitudinal pipes 202, the two nuts 2084 and two sides of the second movable clamp 2087 are fixedly connected with hinge blocks 2086, the two hinge blocks 2086 are hinged with connecting rods 2085 through pin shafts, the connecting rods 2085 can realize the characteristic of steering movement through the pin shafts, the connecting rods 2085 can smoothly push the second movable clamp 2087 to move, the two ends of the second movable clamp 2087 are fixedly connected with second sliding blocks 2088, the second sliding blocks 2088 are slidably connected to the supporting frame 204, the second sliding blocks 2088 slide on the supporting frame 204 smoothly, the second movable clamp 2087 keeps moving smoothly, the second movable clamp 2087 corresponds to the second fixed clamp 210, the second fixed clamp 210 is fixedly connected in the supporting frame 204, the limiting assemblies 208 are matched with the corresponding ball rods 211 and the second fixed clamps 210 and are used for clamping and limiting the upper parts of the two parallel longitudinal pipes 202, and the lower parts of the two longitudinal pipes 202 are provided with corresponding horizontal pipes 201; when the length of the longitudinal tube 202 to be supported is long, different numbers of support frames 204 and telescoping assemblies 205 may be selected for use so as to be adaptable for different lengths of longitudinal tube 202 support.

In this embodiment, through arranging the pipe laying mechanism 200 transversely, thereby the longitudinal pipe 202 can pass between the second movable clamp 2087 and the second fixed clamp 210 in turn, be convenient for construct the equipment between the longitudinal pipe 202, reduce the equipment degree of difficulty, and advance first movable clamp 2061 through the gim peg 2063 and play fixed effect to the bottom of longitudinal pipe 202 through cooperation first fixed clamp 214, then can expand the braced frame 204 in proper order through crossing telescopic arm 2051, make the distance that every braced frame 204 was expanded the same, ensure the equidistant location of longitudinal pipe 202, promote the stability of longitudinal pipe 202, cross telescopic arm 2051 expansion can drive slide rail 2052 motion simultaneously, make ball pole 211 drive screw 2083 and nut 2084 transmission through arc groove 2082 control pivot 2081, make the propulsion of second movable clamp 2087 can press from both sides tight pipeline, thereby can satisfy the multistage equidistance fixed of longitudinal pipe 202 top, avoid traditional problem that leads to construction operation degree of difficulty to increase through welding and iron wire mode, with this can effectively improve the efficiency of construction.

Example 2

Referring to fig. 12-13, it is derived that the telescopic assembly 205 includes a cross telescopic arm 2051, two ends of the cross telescopic arm 2051 are hinged to two connecting blocks 2055, the two connecting blocks 2055 are fixedly connected between the two supporting frames 204, the other two ends of the cross telescopic arm 2051 are hinged to two sliding rails 2052, the sliding rail 2052 above is fixedly connected with the ball rod 211, the sliding rail 2052 is slidably connected to a sliding rail 2053, the sliding rail 2053 is fixedly connected to the supporting frame 204, one end of the sliding rail 2053 is fixedly connected with a stop piece 2054, and a clamping port 2056 is formed in the sliding rail 2053.

In this embodiment, the support frames 204 are connected by the cross telescopic arms 2051, so that a plurality of support frames 204 can be connected together, and the support frames 204 can be folded by the retractility of the cross telescopic arms 2051, so that the support frames 204 can be folded together, thereby greatly reducing the volume to meet the requirement of convenient carrying, and the support frames 204 can be erected by the cross telescopic arms 2051, so that the support frames 204 can be stably erected on the longitudinal pipes 202, and meanwhile, the expanded support frames 204 are increased to fix the longitudinal pipes 202, so that the expansion and contraction characteristics of the device can eliminate the need of on-site construction and can be used after expansion, thereby enabling the construction operation to be simple and convenient, and further accelerating the construction progress.

Example 3

11-13, The telescopic assembly 205 comprises a cross telescopic arm 2051, two ends of the cross telescopic arm 2051 are hinged with two connecting blocks 2055, the two connecting blocks 2055 are fixedly connected between two supporting frames 204, the other two ends of the cross telescopic arm 2051 are hinged with two sliding rails 2052, the sliding rail 2052 above is fixedly connected with the ball rod 211, the sliding rail 2052 is slidably connected with a guide rail 2053, the guide rail 2053 is fixedly connected with the supporting frames 204, one end of the guide rail 2053 is fixedly connected with a stop block 2054, and the guide rail 2053 is provided with a clamping port 2056;

The auxiliary assembly 207 comprises an outer frame 2071, one side of the outer frame 2071 is fixedly connected with a pulley 2073, a plurality of cleaning holes 2075 are formed in the outer frame 2071, the cleaning holes 2075 are penetrated through the longitudinal tube 202, two side walls of the outer frame 2071 are fixedly connected with sliding strips 2072, the sliding strips 2072 can be pulled out from the rails 2074, so that the outer frame 2071 can be removed, meanwhile, the outer frame 2071 and the supporting frame 204 can be conveniently assembled and used, the pulley 2073 can smoothly support the other end of the transversely placed supporting frame 204, the sliding strips 2072 are slidably connected in the rails 2074, and the rails 2074 are fixedly connected to one side of the supporting frame 204.

In this embodiment, after the bottom of the longitudinal tube 202 is positioned by the positioning component 206, the supporting frames 204 are unfolded one by the crossed telescopic arms 2051, the unfolded supporting frames 204 enable the ball rod 211 and the limiting component 208 to cooperate to realize multi-stage clamping of the longitudinal tube 202, so that stability of the longitudinal tube 202 can be maintained, laying quality of the longitudinal tube 202 is improved, the other end of the device is supported by the moving wheel, labor-saving operation can be assisted by constructors, meanwhile, the outer frame 2071 moves along with the supporting frames 204, the cleaning holes 2075 slide along the surface of the longitudinal tube 202, the cleaning holes 2075 can clean the longitudinal tube 202, cleaning operation can be completed in the process of assembling the longitudinal tube 202, and cleaning cotton can be filled in the cleaning holes 2075 for cleaning.

A construction process of an adjustable supporting device for a vertical pipe of a ground source heat pump system comprises the following steps:

S1, when the pipeline is laid, the pipeline laying mechanism 200 is transversely arranged, the longitudinal pipe 202 sequentially passes through the second movable clamp 2087 and the second fixed clamp 210 and passes through the space between the first movable clamp 2061 and the first fixed clamp 214, and then the fixed bolt 2063 is rotated to enable the fixed bolt 2063 to push the first movable clamp 2061, and the first movable clamp 2061 is close to the first fixed clamp 214, so that the first movable clamp 2061 and the first fixed clamp 214 clamp and position the pipeline;

S2, sequentially expanding the support frames 204 through the cross telescopic arms 2051, enabling the sliding rail 2052 to slide to the end part of the guide rail 2053, blocking the position through the stop block 2054, enabling the position of the clamping frame 2091 to correspond to the clamping opening 2056, enabling the second spring 2092 to drive the clamping frame 2091 to reset, enabling the clamping frame 2091 to be clamped into the clamping opening 2056, enabling the position of the cross telescopic arms 2051 to be fixed, and keeping the angle of each support frame 204;

S3, when the crossed telescopic arms 2051 are unfolded to drive the sliding rails 2052 to slide, the sliding rails 2052 are enabled to drive the ball rods 211 to move, the ball rods 211 control the rotating shafts 2081 to rotate through the arc grooves 2082, the rotating shafts 2081 drive the screw rods 2083 to rotate, the screw rods 2083 and the nuts 2084 are in threaded transmission, the nuts 2084 drive the connecting rods 2085 to rotate, the connecting rods 2085 drive the second movable clamps 2087 to move, the second movable clamps 2087 are enabled to match the first fixing clamps 214 to position the longitudinal pipes 202, the longitudinal pipes 202 meet the operation of each section of positioning support, then the connected longitudinal pipes 202 are erected, the lengths of the telescopic rods 2031 are adjusted to extend to the ground to be positioned, and then the horizontal pipes 201 and the longitudinal pipes 202 are connected.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (10)

1. An adjustable supporting device for a vertical pipe of a ground source heat pump system is characterized by comprising a pipeline laying mechanism (200), wherein the pipeline laying mechanism (200) is laid on one side of a basement structure (100);

The pipeline laying mechanism (200) comprises a plurality of longitudinally arranged supporting frames (204), wherein supporting assemblies (203) are arranged on two sides of one supporting frame (204), front and rear sides of the supporting frames (204) are connected through a plurality of telescopic assemblies (205) and used for adjusting the supporting frames (204), a clamping assembly (209) is arranged above the telescopic assemblies (205) and used for positioning the telescopic assemblies (205), and two ball rods (211) are further connected above the telescopic assemblies (205);

The upper portion of supporting frame (204) of top is provided with auxiliary assembly (207), and the below be provided with two locating component (206) in supporting frame (204), locating component (206) and corresponding first fixation clamp (214) cooperation for to the below location of two rows of vertical pipes (202) that set up side by side, the balance all be provided with two spacing subassembly (208) in supporting frame (204), spacing subassembly (208) cooperate with ball pole (211) and second fixation clamp (210) that correspond, are used for the top centre gripping spacing of two rows of vertical pipes (202) side by side, and the below of two rows of vertical pipes (202) is provided with corresponding horizontal pipe (201).

2. An adjustable support device for a ground source heat pump system riser as set forth in claim 1 wherein said positioning assembly (206) comprises a first movable clamp (2061), said first movable clamp (2061) is disposed in a lowermost support frame (204), a first spring (2062) is fixedly connected between said first movable clamp (2061) and said lowermost support frame (204), said first movable clamp (2061) corresponds to a first fixed clamp (214), said longitudinal tube (202) passes through said first movable clamp (2061) and said first fixed clamp (214), said first fixed clamp (214) is fixedly connected in said lowermost support frame (204), and a plurality of hooks (213) are fixedly connected above said uppermost support frame (204).

3. An adjustable support device for a ground source heat pump system riser as set forth in claim 2, wherein a securing bolt (2063) is mounted on one side of said first movable clamp (2061), said securing bolt (2063) is threadably connected to a threaded sleeve (2064), said threaded sleeve (2064) being mounted on a support frame (204);

The two sides of the first movable clamp (2061) are fixedly connected with first sliding blocks (2065), the first sliding blocks (2065) are slidably connected to the supporting frame (204), one side of the lowest supporting frame (204) is fixedly connected with supporting legs (212), and the bottom of the lowest supporting frame (204) is fixedly connected with a plurality of fixing rods.

4. The adjustable support device for the ground source heat pump system vertical pipe according to claim 1, wherein the support assembly (203) comprises two adjusting telescopic rods (2031), ground cones (2032) are fixedly connected to the bottom ends of the adjusting telescopic rods (2031), the top ends of the adjusting telescopic rods (2031) are connected with connecting bases (2035) through universal joints (2033), the two connecting bases (2035) are mounted on connecting frames (2034) through bolts, and the connecting frames (2034) are fixedly connected to one side of the support frame (204).

5. The adjustable support device for the ground source heat pump system vertical pipe is characterized in that the auxiliary assembly (207) comprises an outer frame (2071), one side of the outer frame (2071) is fixedly connected with a pulley (2073), a plurality of cleaning holes (2075) are formed in the outer frame (2071), a longitudinal pipe (202) penetrates through the cleaning holes (2075), sliding strips (2072) are fixedly connected to two side walls of the outer frame (2071), the sliding strips (2072) are slidably connected in a track (2074), and the track (2074) is fixedly connected to one side of the support frame (204).

6. The adjustable support device for the ground source heat pump system vertical pipe of claim 1, wherein the limiting component (208) comprises a rotating shaft (2081) and two connecting rods (2085), arc-shaped grooves (2082) are formed in the rotating shaft (2081), and the ball rods (211) are slidably connected with the arc-shaped grooves (2082).

7. The adjustable support device for the ground source heat pump system vertical pipe is characterized in that screw rods (2083) are fixedly connected to two ends of the rotating shaft (2081), the screw rods (2083) are rotatably installed on the support frame (204) through bearings, nuts (2084) are connected to the screw rods (2083) in a threaded mode, hinging blocks (2086) are fixedly connected to two sides of the two nuts (2084) and the two sides of the second movable clamp (2087), connecting rods (2085) are hinged to the two hinging blocks (2086) through pin shafts, second sliding blocks (2088) are fixedly connected to two ends of the second movable clamp (2087), the second sliding blocks (2088) are connected to the support frame (204) in a sliding mode, the second movable clamp (2087) corresponds to the second fixing clamp (210), and the second fixing clamp (210) is fixedly connected to the support frame (204).

8. The adjustable support device for the ground source heat pump system vertical pipe is characterized in that the telescopic component (205) comprises a cross telescopic arm (2051), two ends of the cross telescopic arm (2051) are hinged to two connecting blocks (2055), the two connecting blocks (2055) are fixedly connected between two support frames (204), the other two ends of the cross telescopic arm (2051) are hinged to two sliding rails (2052), the sliding rail (2052) above the sliding rail is fixedly connected with a ball rod (211), the sliding rail (2052) is slidably connected to a guide rail (2053), the guide rail (2053) is fixedly connected to the support frames (204), one end of the guide rail (2053) is fixedly connected with a stop block (2054), and a clamping opening (2056) is formed in the guide rail (2053).

9. The adjustable support device for a ground source heat pump system vertical pipe as set forth in claim 8, wherein the clamping assembly (209) comprises a clamping frame (2091), the clamping frame (2091) is inserted into the clamping opening (2056), and a telescopic rod (2093) and a second spring (2092) are fixedly connected between the clamping frame (2091) and the lower part of the upper sliding rail (2052).

10. A construction process of an adjustable support device for a vertical tube of a ground source heat pump system according to any one of claims 1 to 9, comprising the steps of:

S1, when the pipeline is laid, the pipeline laying mechanism (200) is transversely arranged, a longitudinal pipe (202) sequentially passes through a second movable clamp (2087) and a second fixed clamp (210) and passes through a space between a first movable clamp (2061) and a first fixed clamp (214), and then a fixing bolt (2063) is rotated to enable the fixing bolt (2063) to push the first movable clamp (2061) to enable the first movable clamp (2061) to be close to the first fixed clamp (214), so that the first movable clamp (2061) and the first fixed clamp (214) clamp and position the pipeline;

S2, sequentially unfolding the supporting frames (204) through the crossed telescopic arms (2051), enabling the sliding rail (2052) to slide to the end part of the guide rail (2053), blocking the position through the stop block (2054), enabling the position of the clamping frame (2091) to correspond to the clamping opening (2056), enabling the second spring (2092) to drive the clamping frame (2091) to reset, enabling the clamping frame (2091) to be clamped into the clamping opening (2056), enabling the position of the crossed telescopic arms (2051) to be fixed, and keeping the angle of each supporting frame (204);

S3, when the crossed telescopic arm (2051) is unfolded to drive the sliding rail (2052) to slide, the sliding rail (2052) is enabled to drive the ball rod (211) to move, the ball rod (211) controls the rotating shaft (2081) to rotate through the arc-shaped groove (2082), the rotating shaft (2081) drives the screw rod (2083) to rotate, the screw rod (2083) and the nut (2084) are in threaded transmission, the nut (2084) is enabled to drive the connecting rod (2085) to rotate, the connecting rod (2085) is enabled to push the second movable clamp (2087) to move, the second movable clamp (2087) is enabled to be matched with the first fixing clamp (214) to position the longitudinal pipe (202), the longitudinal pipe (202) meets the operation of each section of positioning support, then the connected longitudinal pipe (202) is erected, the length of the telescopic rod (2031) is adjusted to extend to the ground to be positioned, and then the horizontal pipe (201) and the longitudinal pipe (202) are connected.