CN111236709A - Container type monitoring station applied to comprehensive energy system - Google Patents

Abstract

The invention discloses a container type monitoring station applied to a comprehensive energy system, which comprises: the foundation assembly comprises foundation bases distributed in an array manner and connecting rods connected between the adjacent foundation bases; the foundation base comprises foundation plates, and the upper parts of all the foundation plates distributed on the periphery are also vertically fixed with inserting columns; a support post including a corner post and a middle post, both having a channel on the inside that fits the insert post; in the peripheral base, corner columns extending vertically are respectively inserted into the inserting columns at four corners, and middle columns extending vertically are respectively inserted into the other inserting columns; the outer wall fixing grooves of the adjacent supporting columns are opposite to each other and can form an inserting space; the wall plate splicing block can be spliced in any splicing space; and a capping assembly that caps the top of the unitary structure. All components of the invention are prefabricated, and the monitoring station can be built only by simple assembly on site.

Description

Container type monitoring station applied to comprehensive energy system

Technical Field

The invention relates to the technical field of comprehensive energy systems, in particular to a container type monitoring station applied to a comprehensive energy system.

Background

The comprehensive energy system is characterized in that advanced physical information technology and innovative management modes are utilized in a certain area, multiple energy sources such as coal, petroleum, natural gas, electric energy and heat energy in the area are integrated, and coordinated planning, optimized operation, cooperative management, interactive response and complementary mutual assistance among multiple heterogeneous energy subsystems are achieved. The energy utilization efficiency is effectively improved and the sustainable development of energy is promoted while the diversified energy utilization requirements in the system are met. In a comprehensive energy system or an energy internet system, a new energy power generation system is an important part and is also a necessary component for perfecting the comprehensive energy system and realizing sufficient supply of energy and a green environmental protection concept. In an existing new energy power generation system (photovoltaic power generation and wind power generation), particularly in a distributed photovoltaic power generation system, a power station control room or an electric room (having functions of power system control, information acquisition, data sharing, communication and the like) needs to be equipped in a photovoltaic arrangement area, but the existing control room is mostly built by building a traditional concrete or brick-concrete structure, so that the new energy power generation system is high in cost, labor-consuming and time-consuming, cannot flexibly adapt to the area arrangement condition of the new energy which is distributed in a large number, and is low in integration level.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made in view of the problems occurring in the prior art.

Therefore, an object of the present invention is to provide a container type monitoring station applied to an integrated energy system, which can solve the defects that the power station control room in the prior art is high in construction cost, labor-consuming and time-consuming, and cannot flexibly adapt to the area arrangement situation where new energy is distributed in many places.

In order to solve the technical problems, the invention provides the following technical scheme: a container formula control station for comprehensive energy system, it includes: the foundation assembly comprises foundation bases distributed in an array manner and connecting rods connected between the adjacent foundation bases along the transverse direction and the longitudinal direction; the foundation base comprises foundation plates, and the upper parts of all the foundation plates distributed on the periphery are also vertically fixed with inserting columns; a support post including a corner post and an intermediate post, both having a channel on the interior that fits within the peripheral profile of the insert post; in each base on the periphery, corner columns extending vertically are respectively inserted and detachably fixed on the inserting columns at four corners, and middle columns extending vertically are respectively inserted and detachably fixed on the other inserting columns; a pair of adjacent outer side surfaces of the corner columns are provided with vertical first outer wall fixing grooves; a pair of outer side faces, opposite to each other, of the middle column are provided with vertical second outer wall fixing grooves; the outer wall fixing grooves of the adjacent supporting columns are opposite to each other and can form an inserting space; the wall plate splicing blocks can be spliced in any splicing space, and a plugged outer wall is formed between adjacent supporting columns corresponding to the splicing space; the independent door comprises a door frame matched with the inserting space and a door leaf rotatably arranged in the door frame; the independent door can be fixedly inserted into any insertion space formed among the supporting columns, and the rest insertion spaces are inserted and plugged through the wallboard splicing blocks; and the cover top component covers the top of the integral structure and is detachably connected with the top of each supporting column.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the connecting rod comprises a straight rod section and bending heads which are centrally and symmetrically distributed at two ends of the straight rod section; four L-shaped embedded grooves which are distributed annularly and are centrosymmetric are arranged at the bottom of the foundation plate; each L-shaped embedded groove is matched with the end structure of the connecting rod and comprises an inner section corresponding to the bending head and an outer section corresponding to the end of the straight rod section; the periphery of the foundation plate is provided with four outer side faces parallel to the inner sections, and each outer side face is provided with a first screw hole which is vertical and communicated to the corresponding inner section; two ends of the connecting rod are respectively embedded into a pair of L-shaped embedded grooves which are opposite to each other on the adjacent foundation plates, and the corresponding bending heads are extruded through first bolts screwed into the first screw holes.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the bottom of each outer wall fixing groove on each supporting column is provided with a first through hole communicated to the channel of the supporting column, and the inserting column is provided with a second screw hole corresponding to the first through hole; when the inserted column is inserted into the channel of the corresponding support column, the first through hole is opposite to the second screw hole, and the first through hole and the second screw hole are sequentially penetrated through by the screwed second bolt.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the wallboard splicing block comprises a shell with a closed outer part and an insulating layer filled in the shell; the thickness of the wallboard splicing block is matched with the width of the outer wall fixing groove, and positive integers of wallboard splicing blocks with the same specification can be vertically arranged in the splicing space; and two sides of the shell are concave inwards to form an avoidance groove which corresponds to the second bolt and is communicated up and down.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the coping component comprises a supporting raft connected with the top of each supporting column, a top plate covering the upper layer of the supporting raft and corner wrapping strips surrounding and detachably fixed on the periphery of the top plate; the supporting raft comprises an outer frame, a plurality of supporting beams transversely fixed in the outer frame and pins fixed at the bottom of the outer frame and capable of being inserted into top channels of the supporting columns; the corner wrapping strips are wrapped on the top plate and the outer edges of the tops of the support columns, second through holes communicated into the channels are formed in the outer side faces of the tops of the support columns, corresponding third through holes are formed in the corner wrapping strips, corresponding third screw holes are formed in the pins inserted into the channels of the tops of the support columns, the third through holes, the second through holes and the third screw holes are opposite to each other, and the third through holes, the second through holes and the third screw holes sequentially penetrate through the top plate, the support columns and the pins for fixing.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: at least one part of the middle column is also provided with a vertical inner wall fixing groove on the other side surface except the side surface where the second outer wall fixing groove is located, the opening of the inner wall fixing groove is inward, and the width of the opening is matched with the thickness of the wallboard splicing block.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the upper surface of the foundation plate is higher than the top surfaces of the connecting rods in the vertical height to form a height difference, and the top surfaces of the connecting rods are consistent in height; the foundation assembly further comprises a support plate covering the tops of all the joint rods and a floor laid on the upper layer of the support plate; the thickness of the supporting plate is equal to the height difference between the upper surface of the foundation plate and the top surface of the connecting rod, the edge of the supporting plate is provided with a notch corresponding to the peripheral outline of the foundation plate, and each foundation plate can be just embedded into the corresponding notch.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the stretching component is connected between the two base seats at the diagonal corners in a cross way; the stretching assembly comprises a first pull rod, a second pull rod, a connecting piece for connecting the inner ends of the first pull rod and the second pull rod, and grip modules which are respectively arranged at the outer ends of the first pull rod and the second pull rod and can be detachably connected with the corner of the foundation plate; the gripper modules of the first pull rod and the second pull rod of the same stretching assembly are respectively connected with a pair of base plates which are diagonally opposite to each other, and four corners of each base plate are respectively provided with connecting holes matched with the gripper modules.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the connecting piece comprises a first connecting end integrally formed at the inner end of the first pull rod, a second connecting end integrally formed at the inner end of the second pull rod, and a locking ring sleeved on the periphery of the first connecting end; the first connecting end is internally provided with a slideway with an opening at the end part, and the slideway is communicated with the outside through a seam extending along the side edge of the slideway synchronously; the second connecting end is matched with the slideway and inserted into the slideway, the end part of the second connecting end is hinged with an extrusion block, the outer edge of the extrusion block is provided with an extrusion bulge, the extrusion block is also fixed with a poke rod extending out of the slideway from the seam, and the tail end of the poke rod is provided with a limiting block; when the poke rod is rotated and embedded into the slit, the extrusion protrusion can extrude the inner side wall of the slideway, and can slide and limit the locking ring at the periphery of the poke rod.

As a preferable aspect of the container type monitoring station applied to the integrated energy system of the present invention, wherein: the gripper module comprises a clamping plate integrally formed at the outer end of the first pull rod or the second pull rod, a pair of clamping jaws which are crossly arranged in an interlayer of the clamping plate and can rotate relatively, and a driving piece which can drive the clamping jaws to rotate relatively to control the opening size of the outer end of the clamping jaws; the two clamping jaws are hinged at the tail end of the clamping plate through a first pin shaft, and a jaw is formed at the outer ends of the two clamping jaws; the clamping plate comprises a first strip plate and a second strip plate which are parallel to each other, sliding grooves extending along the length direction of the gripper module are formed in the inner side walls of the first strip plate and the second strip plate, sliding seams which are consistent with the sliding grooves in direction and are communicated with each other are formed in the outer side wall of the second strip plate, and the width of each sliding seam is smaller than that of each sliding groove; the driving piece comprises a pair of connecting pieces which are parallel to each other and can be respectively embedded into the two sliding grooves, a connecting column fixed between the connecting pieces, and a pair of driving rods which are hinged to the outer ends of the connecting pieces at the same time, and the tail ends of the two driving rods are respectively hinged to the inner ends of the two clamping jaws through second pin shafts; a through fourth screw hole is formed in the connecting column, and a fourth bolt is rotated in the fourth screw hole and penetrates through the fourth screw hole; an elastic guy cable is connected between the inner ends of the two claws, bypasses the connecting column and is in a tensioning state under the stretching of the connecting column.

The invention has the beneficial effects that: all components of the invention are prefabricated, the monitoring station can be built only by simply assembling on site, the assembling process is simple and quick, a large amount of manpower and materials are not needed, the cost is lower, the invention is suitable for the use of large-scale and large-batch distributed power generation systems, the site setting is flexible, and the site selection requirement is not high. Meanwhile, the monitoring station is internally provided with at least a control system, local monitoring equipment, communication equipment, network facilities, storage equipment and other existing equipment related to power grid control, so that the integration level is high.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is an external structural view of the container type monitoring station.

Fig. 2 is an exploded view of the container monitoring station.

Fig. 3 is a lower structural view of the base unit.

FIGS. 4 to 6 are detailed views of the structure at three points A, B, C in FIG. 3.

FIG. 7 is a horizontal sectional view of the base plate.

Fig. 8 is a horizontal cross-section of the container-type monitoring station at the bottom of a support column.

Fig. 9 is a node explosion diagram of the container type monitoring station.

Fig. 10 and 11 are detailed views of the structure at two points D, E in fig. 9.

Fig. 12 is an exploded view of a tension assembly and a detail view of a portion thereof.

Figure 13 is an assembled block diagram of a tension module and a detail view of a portion of the same.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

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 than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is 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.

Referring to fig. 1 to 11, an embodiment of the present invention provides a container type monitoring station applied to an integrated energy system, which is convenient to assemble and disassemble, has good flexibility and mobility, does not occupy space, and has high integration level.

The container type monitoring station comprises a base assembly 100 serving as a bearing foundation, a plurality of support columns 200 fixed on the base assembly 100, wall plate segments 300 sealed at the periphery, an independent door 400 positioned at one side of the container type monitoring station, and a cover top assembly 500 covered at the top of the integral structure.

The base assembly 100 includes base bases 101 arranged in a rectangular array in a dot shape, and coupling bars 102 coupled between the adjacent base bases 101 in a lateral direction and a longitudinal direction. The base bases 101 are provided with two different specifications, and among the base bases 101 in the rectangular array, the base bases 101 located on the periphery are unified to use the same specification, and the base bases 101 of the specification include a horizontal base plate 101a and insertion posts 101b vertically fixed on the upper portion of the base plate 101 a.

While the base chassis 101 of another specification includes only the base plate 101a without the insert posts 101 b. Among the base bases 101 in the rectangular array, the remaining base bases 101 located within one circumference of the outer periphery may selectively use the base 101 with the stud 101b and the base 101 without the stud 101b (e.g., the remaining base bases 101 may all use the base 101 without the stud 101 b).

The base plates 101a are preferably square plates having a certain thickness, and include four sides having a periphery, and the sides between the adjacent base plates 101a are parallel to each other and face each other.

The support column 200 is equipped with two different specifications, corner columns 201 and middle columns 202.

The corner post 201 and the center post 202 are the same in that: the inside of the corner post 201 and the middle post 202 are provided with a channel D matching the peripheral contour of the insert post 101b (for example, if the cross section of the insert post 101b of the present invention is square, the channel D matches the contour), and preferably, the channel D of the corner post 201 and the middle post 202 are the same in size and structure and are vertically through. In each base 101 of the outermost circumference of the matrix distribution, a corner column 201 extending vertically is respectively inserted and detachably fixed to the insert columns 101b at four corners, and a middle column 202 extending vertically is respectively inserted and detachably fixed to the other insert columns 101b of the circumference of the periphery.

The difference between the corner post 201 and the center post 202 is that: a pair of adjacent outer side surfaces on the corner column 201 are respectively provided with a first outer wall fixing groove 201a, the first outer wall fixing grooves 201a are of a vertically extending groove-shaped structure, and two ends of the first outer wall fixing grooves are communicated; a pair of outer side surfaces of the middle column 202 opposite to each other are respectively provided with a vertical second outer wall fixing groove 202a, and the structural form of the second outer wall fixing groove 202a is completely the same as that of the first outer wall fixing groove 201 a. The outer wall fixing grooves (including the first outer wall fixing groove 201a and the second outer wall fixing groove 202a) of the adjacent supporting columns 200 are opposite to each other, and can form the insertion space J therebetween.

The thickness of the wall panel splicing block 300 is matched with the width of the outer wall fixing groove, the wall panel splicing block can be spliced in any splicing space J, and a plugged outer wall is formed between the adjacent supporting columns 200 corresponding to the splicing space J.

The independent door 400 exists as an independent module, which includes a door frame 401 fitted to the insertion space J and a door leaf 402 rotatably disposed in the door frame 401. The independent door 400 can be directly inserted and fixed in any inserting space J formed between the supporting columns 200, and the rest inserting spaces J are inserted and blocked through the wall plate splicing blocks 300, so that a customer can set the door leaf at any position according to the requirement of the customer or the objective requirement of field space arrangement, and the independent door is more selective.

The roof assembly 500 is removably attached to the top of each support column 200 and can be capped over the top of the overall structure as a roof guard.

Based on the above, all components of the invention are prefabricated, the monitoring station can be built only by simply assembling on site, the assembling process is simple and rapid, a large amount of manpower and materials are not needed, the cost is low, the invention is suitable for the use of large-scale and large-batch distributed power generation systems, the site setting is flexible, and the site selection requirement is not high. Meanwhile, the monitoring station is internally provided with at least a control system, local monitoring equipment, communication equipment, network facilities, storage equipment and other existing equipment related to power grid control, so that the integration level is high.

Further, all the base bases 101 and the joint rods 102 of the present invention are unified components, and can be optionally assembled on site. The joint rod 102 includes a straight rod segment 102a and bending heads 102b centrally and symmetrically disposed at both ends of the straight rod segment 102a, such that the joint rod 102 forms an "S" shaped structure.

The bottom of the foundation plate 101a is provided with four L-shaped embedded grooves 101a-1 which are distributed annularly and are centrosymmetric. Each L-shaped buried groove 101a-1 is fitted to an end structure of the engaging rod 102, and specifically includes an inner section 101a-11 corresponding to the bending head 102b and an outer section 101a-12 corresponding to an end of the straight rod section 102 a. The inner section 101a-11 and the outer section 101a-12 in the same L-shaped buried channel 101a-1 are perpendicular to each other. Four side surfaces of the periphery of the base plate 101a are respectively corresponding to and parallel to the four inner sections 101a-11 one by one, and a first screw hole K-1 which is vertical and communicated to the corresponding inner section 101a-11 is arranged on each outer side surface.

Both ends of the joint rod 102 can be respectively embedded into a pair of L-shaped embedded grooves 101a-1 facing each other on the adjacent base plate 101a, and the corresponding bending head 102b is pressed by a first bolt S-1 screwed into the first screw hole K-1, so that the end of the joint rod 102 is fixed in the corresponding L-shaped embedded groove 101 a-1. Because four L-shaped embedded grooves 101a-1 on the base plate 101a are centrosymmetric, and any side of the embedded grooves can be connected with the connecting rod 102, the concrete orientation of the outer side surface of the base 101 does not need to be considered in the actual process of assembling the connecting rod 102 and the base 101, so that the installation process is more convenient and faster.

Furthermore, the bottom of each outer wall fixing groove on each supporting column 200 is provided with a first through hole C-1 communicated to the channel D, and the inserting column 101b is provided with a second screw hole K-2 corresponding to the first through hole C-1; when the insert column 101b is inserted into the channel D of the corresponding support column 200, the first through hole C-1 and the second screw hole K-2 are opposite to each other, and the screwed second bolt S-2 can sequentially pass through the first through hole C-1 and the second screw hole K-2, so that the support column 200 can be detachably fixed on the corresponding insert column 101 b.

Further, the wall panel module 300 includes a casing 301 enclosed outside and an insulating layer 302 filled inside the casing 301, wherein the insulating layer 302 is made of existing building insulating filling materials. The thickness of wallboard piece 300 cooperates in the width of outer wall fixed slot, and grafting space J can arrange the wallboard piece 300 that has the same specification of positive integer in vertical, promptly: every grafting space J all needs a plurality of wallboards of piling up the linking from top to bottom to splice the outer wall that forms this department, and the outward flange of adjacent wallboard splicing piece 300 extrudees closely to cooperate each other, and is preferred, is provided with the protruding combination of bar recess and the bar that can interlock each other on the edge that wallboard splicing piece 300 links up each other, can guarantee the compactness and the waterproof nature of linking up between adjacent wallboard splicing piece 300 edge.

In addition, the two sides of the casing 301 are recessed to form an avoidance groove 301a corresponding to the second bolt S-2 and penetrating up and down, so that the wall panel split 300 is not obstructed by the stroke of the second bolt S-2 in the process of being inserted into the plugging space J downwards. The second bolt S-2 is arranged in the outer wall fixing groove and has the following functions: the outer wall fixing groove and the avoiding groove 301a together surround the connection point of the second bolt S-2, so that the opening position of the second bolt S-2 is not exposed, and therefore the waterproof performance is excellent.

Further, the canopy assembly 500 includes a support raft 501 attached to the top of each support column 200, a top plate 502 covering the upper layer of the support raft 501, and a corner wrap strip 503 surrounding and detachably fixed to the periphery of the top plate 502.

The support raft 501 includes an outer frame 501a, a plurality of support beams 501b transversely fixed in the outer frame 501a, and pins 501c fixed to the bottom of the outer frame 501a and capable of being inserted into the top channels D of the respective support columns 200. The supporting raft 501 may be an integrated structure or an assembly structure, and when the assembly structure is adopted, the outer frame 501a, the supporting beams 501b, and the pins 501c may be separate members, and the members are assembled and connected by bolts to form a whole.

The angle wrapping strip 503 is preferably an angle steel, which wraps the top plate 502 and the outer edge of the top of each supporting column 200, the outer side surface of the top of each supporting column 200 is provided with a second through hole C-2 communicated to the channel D, the angle wrapping strip 503 is provided with a corresponding third through hole C-3, and the pin 501C inserted into the channel D at the top of the supporting column 200 is provided with a corresponding third screw hole K-3. The third through hole C-3, the second through hole C-2 and the third screw hole K-3 can be opposite to each other, and the third bolt S-3 sequentially penetrates through the third through hole C-3, the second through hole C-2 and the third screw hole K-3 to be fixed, meanwhile, the support raft 501, the top plate 502 and the corner wrapping strip 503 are fixed, in addition, the tops of all the support columns 200 are connected, and the integrity and the stability of the frame structure are improved.

Further, the present invention sets: for some (or all) of the middle columns 202, vertical inner wall fixing grooves 202b are further formed on the other side surface except the side surface where the second outer wall fixing grooves 202a are formed, the openings of the inner wall fixing grooves 202b face inward, and the width of the openings is matched with the thickness of the wall panel splicing block 300. Meanwhile, when there is the middle column 202 having the inner wall fixing groove 202b, the corresponding base 101 located within one circumference of the periphery also has the insert column 101b, and a new middle column 202 is inserted and fixed on the insert column 101b, the middle column 202 is opposite to the middle column 202 having the inner wall fixing groove 202b, and the second outer wall fixing groove 202a of the middle column 202 is opposite to the inner wall fixing groove 202b, so as to form a new insertion space J inside the box body, into which the wall panel split panels 300 can be inserted and fixed, for forming an internal partition wall or partition plate.

Preferably, the present invention sets: at least 3 basic bases 101 (3 are selected in the invention) are arranged in each row along the width direction of the container type monitoring station; at least 4 base bases 101 (6 are selected in the present invention) are arranged in each row along the length of the container type monitoring station.

Further, when the adapter bars 102 are installed in the L-shaped buried grooves 101a-1, the upper surfaces of the base plates 101a are higher in vertical height than the top surfaces of the adapter bars 102, forming a step, and the top surfaces of the respective adapter bars 102 are uniform in height.

The foundation assembly 100 further includes a support plate 103 covering the top of all the joint bars 102 and a floor 104 laid on the upper layer of the support plate 103; the thickness of the supporting plate 103 is equal to the height difference between the upper surface of the base plate 101a and the top surface of the connecting rod 102, and the edge of the supporting plate 103 is provided with an avoiding notch 103a corresponding to the peripheral contour of the base plate 101a, and each base plate 101a can be just embedded into the corresponding avoiding notch 103a, so that the upper surface of the supporting plate 103 and the upper surface of each base plate 101a can jointly form a supporting plane for supporting the floor 104.

Further, as shown in fig. 3, 7, 12 and 13, the container type monitoring station of the present invention further includes a stretching assembly 600 cross-connected between two base pedestals 101 at diagonal angles.

The stretching assembly 600 comprises a first pull rod 601, a second pull rod 602, a connecting piece 603 for connecting the inner ends of the first pull rod and the second pull rod, and a gripper module 604 which is respectively arranged at the outer ends of the first pull rod and the second pull rod and can be detachably connected with the corner of the foundation plate 101 a; the gripper modules 604 of the first pull rod 601 and the second pull rod 602 of the same stretching assembly 600 are respectively connected with a pair of base plates 101a which are diagonally opposite to each other, and four corners of each base plate 101a are respectively provided with a connecting hole 101a-2 which is matched with the gripper module 604, and the gripper module 604 can be clamped into the corresponding connecting hole 101a-2 to realize locking.

Specifically, the connecting member 603 includes a first connecting end 603a integrally formed on the inner end of the first pull rod 601, a second connecting end 603b integrally formed on the inner end of the second pull rod 602, and a locking ring 603c sleeved on the periphery of the first connecting end 603 a.

The first connecting end 603a has an open-ended slide 603a-1 therein, and the slide 603a-1 is communicated with the outside through a slit 603a-2 whose side edge extends synchronously.

The second connection end 603b is a bar-shaped structure fitted to the slide 603a-1 and inserted therein to be relatively slidable. The end of the second connecting end 603b is hinged with an extrusion block 603b-1, the outer edge of the extrusion block 603b-1 is provided with an extrusion protrusion 603b-2, and the extrusion protrusion 603b-2 is preferably made of a tough wear-resistant pressure-resistant material, such as rubber. A poke rod 603b-3 extending out of the sliding way 603a-1 from the seam 603a-2 is further fixed on the extrusion block 603b-1, and a convex limiting block 603b-4 is arranged at the tail end of the poke rod 603 b-3;

when the poke rod 603b-3 is rotated and gradually inserted into the slit 603a-2, the extrusion protrusion 603b-2 can gradually extrude the inner side wall of the slide way 603a-1, if the locking ring 603c is slid and limited on the periphery of the poke rod 603b-3, the poke rod 603b-3 can be prevented from being reversely rotated outwards, so that the extrusion protrusion 603b-2 is continuously pressed tightly on the inner side wall of the extrusion slide way 603a-1, and finally the second connecting end 603b can not be separated from the slide way 603 a-1.

Further, the gripper module 604 of the present invention comprises a clamping plate 604a integrally formed at the outer end of the first pull rod 601 or the second pull rod 602, a pair of jaws 604b crosswise arranged in the interlayer of the clamping plate 604a and capable of rotating relatively, and a driving member 604c capable of driving the two jaws 604b to rotate relatively to control the opening of the outer end thereof.

Specifically, two jaws 604b are hinged at the end of the clamping plate 604a through a first pin 604d, and a jaw is formed at the outer end thereof; the connecting hole 101a-2 on the base plate 101a is a passage passing through the corner thereof, and the two claws 604b can be inserted into both ends of the connecting hole 101a-2 from the left and right, respectively, to form locking.

The clamp plate 604a includes a first strip 604a-1 and a second strip 604a-2 parallel to each other, the inner side walls of the first strip 604a-1 and the second strip 604a-2 are respectively provided with a sliding slot H extending along the length direction of the gripper module 604, in addition, the outer side wall of the second strip 604a-2 is further provided with a sliding seam H-1 which is consistent with the direction of the sliding slot H and is communicated with each other, and the width of the sliding seam H-1 is smaller than that of the sliding slot H.

The driving piece 604c comprises a pair of connecting pieces 604c-1 which are parallel to each other and can be respectively embedded into the two sliding grooves H, a connecting column 604c-2 fixed between the connecting pieces 604c-1, and a pair of driving rods 604c-3 which are hinged at the outer ends of the connecting pieces 604c-1, and the tail ends of the two driving rods 604c-3 are respectively hinged with the inner ends of the two claws 604b through second pin shafts 604 e; therefore, the size of the jaw at the outer end of the two jaws 604b can be controlled by pushing the driving member 604c to slide in the sliding slot H.

The connecting column 604c-2 is internally provided with a through fourth screw hole K-4, a fourth bolt S-4 is rotated in the fourth screw hole K-4 and penetrates through the fourth screw hole K-4, the fourth bolt S-4 also penetrates through the sliding slot H-1, and the bolt head of the fourth bolt is positioned outside the sliding slot H-1. An elastic cable 604f (e.g., an elastic rubber rope) is connected between the inner ends of the two claws 604b, and the elastic cable 604f passes around the connecting column 604c-2 and is under tension under the tension of the connecting column 604 c-2.

When it is desired to install the stretching assembly 600 between two diagonally opposite base chassis 101, the following steps may be performed:

firstly, sliding the locking ring 603c into the first pull rod 601, then inserting the second connecting end 603b into the slideway 603a-1 of the first connecting end 603a, and ensuring that the poke rod 603b-3 extends out of the slit 603 a-2;

loosening the fourth bolt S-4 on the first pull rod 601, and pushing the fourth bolt S-4 forward (or under the tension of the elastic pull rope 604f) to open the jaws of the two jaws 604 b; respectively aligning the outer end heads of the two clamping jaws 604b to the left end and the right end of a connecting hole 101a-2 to be connected of one of the base plates 101a, pulling a fourth bolt S-4 backwards to enable the outer end heads of the two clamping jaws 604b to be respectively clamped into the connecting hole 101a-2, and then screwing the fourth bolt S-4 to enable the inner end of the bolt rod of the fourth bolt S-4 to extrude the bottom of the sliding groove H of the first plate 604a-1 to form locking of the integral structure of the driving piece 604 c; thus, the connection of the first tie bar 601 with one of the base plates 101a is completed;

thirdly, the connection between the second pull rod 602 and the other base plate 101a can be completed according to the same method as the steps;

fourthly, the first pull rod 601 and the second pull rod 602 are pulled, so that the second connecting end 603b is inserted into the slideway 603a-1 of the first connecting end 603a as much as possible, and due to the pulling force, the two crossed jaws 604b have the tendency of being straightened (the jaws are reduced), and can be more firmly snapped into the connecting hole 101 a-2;

fifthly, the poke rod 603b-3 is rotated and gradually inserted into the slit 603a-2, the extrusion protrusion 603b-2 can gradually extrude the inner side wall of the slide way 603a-1, the locking ring 603c slides and is limited on the periphery of the poke rod 603b-3, so that the extrusion protrusion 603b-2 is continuously pressed on the inner side wall of the extrusion slide way 603a-1, and finally the second connecting end 603b cannot be separated from the slide way 603a-1, and the connection locking between the first pull rod 601 and the second pull rod 602 is completed.

Further, the connecting member 603 is not located at the center of the stretching assembly 600 in the present invention, so as to avoid the stroke conflict between the two stretching assemblies 600 installed in a crossed manner, preferably, the longer of the first pull rod 601 and the second pull rod 602 is provided with a bending section W thereon, and the bending section W is recessed towards the side to form a stroke concave trend, so as to ensure that the two stretching assemblies 600 in a crossed manner cannot generate the stroke conflict.

It is important to note that the construction and arrangement of the present 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., temperatures, pressures, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited 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 this invention. 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 inventions. Therefore, the present invention is not limited to a particular embodiment, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Moreover, 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 unrelated to the presently contemplated best mode of carrying out the invention, or those unrelated to enabling 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, without undue experimentation.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, 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 modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (10)

1. The utility model provides a be applied to comprehensive energy system's container formula control station which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the base assembly (100) comprises base bases (101) distributed in an array and connecting rods (102) which are connected between the adjacent base bases (101) along the transverse direction and the longitudinal direction; the foundation base (101) comprises foundation plates (101a), and inserting columns (101b) are vertically fixed at the upper parts of the foundation plates (101a) distributed on the periphery;

a support post (200) comprising a corner post (201) and an intermediate post (202), both having a channel (D) inside that fits the peripheral profile of the insert post (101 b); in each base (101) on the periphery, corner columns (201) extending vertically are respectively inserted and detachably fixed on the inserting columns (101b) at four corners, and middle columns (202) extending vertically are respectively inserted and detachably fixed on the other inserting columns (101 b); a pair of adjacent outer side surfaces of the corner columns (201) is provided with a vertical first outer wall fixing groove (201 a); a pair of outer side faces of the middle column (202) opposite to each other are provided with vertical second outer wall fixing grooves (202 a); the outer wall fixing grooves of the adjacent supporting columns (200) are opposite to each other, and an inserting space (J) can be formed;

the wall plate splicing blocks (300) can be spliced in any splicing space (J) and form a plugged outer wall between adjacent supporting columns (200) corresponding to the splicing space (J);

an independent door (400) including a door frame (401) fitted to the insertion space (J) and a door leaf (402) rotatably disposed in the door frame (401); the independent door (400) can be fixedly inserted into any insertion space (J) formed among the supporting columns (200), and the rest insertion spaces (J) are inserted and plugged through the wall plate splicing blocks (300); and the number of the first and second groups,

a capping assembly (500) that caps the top of the unitary structure and is removably attached to the top of each support post (200).

2. The container type monitoring station for the integrated energy system according to claim 1, wherein: the joint rod (102) comprises a straight rod segment (102a) and bending heads (102b) which are distributed at two ends of the straight rod segment (102a) in a centrosymmetric manner;

four L-shaped embedded grooves (101a-1) which are distributed annularly and are centrosymmetric are arranged at the bottom of the foundation plate (101 a); each L-shaped embedded groove (101a-1) is matched with the end structure of the connecting rod (102) and comprises an inner section (101a-11) corresponding to the bending head (102b) and an outer section (101a-12) corresponding to the end of the straight rod segment (102 a); the periphery of the foundation plate (101a) is provided with four outer side faces parallel to the inner sections (101a-11), and each outer side face is provided with a first screw hole (K-1) which is vertical and communicated to the corresponding inner section (101 a-11);

two ends of the connecting rod (102) are respectively embedded into a pair of L-shaped embedding grooves (101a-1) which are opposite to each other on the adjacent foundation plate (101a), and the corresponding bending head (102b) is extruded through a first bolt (S-1) screwed into the first screw hole (K-1).

3. The container type monitoring station for the integrated energy system according to claim 1 or 2, wherein: the bottom of each outer wall fixing groove on each supporting column (200) is provided with a first through hole (C-1) communicated to the channel (D) of the supporting column, and the inserting column (101b) is provided with a second screw hole (K-2) corresponding to the first through hole (C-1); when the insert column (101b) is inserted into the channel (D) of the corresponding support column (200), the first through hole (C-1) and the second screw hole (K-2) are opposite to each other, and the first through hole (C-1) and the second screw hole (K-2) are sequentially penetrated through a screwed second bolt (S-2).

4. The container type monitoring station for the integrated energy system according to claim 3, wherein: the wall panel tile (300) comprises a shell (301) with an outer part closed and an insulating layer (302) filled in the shell (301);

the thickness of the wall plate splicing block (300) is matched with the width of the outer wall fixing groove, and positive integer numbers of wall plate splicing blocks (300) with the same specification can be vertically arranged in the inserting space (J); and two sides of the shell (301) are recessed to form avoidance grooves (301a) which correspond to the second bolts (S-2) and are vertically communicated.

5. The container type monitoring station for the integrated energy system according to any one of claims 1, 2 or 4, wherein: the roof assembly (500) comprises a support raft (501) connected with the top of each support column (200), a top plate (502) covering the upper layer of the support raft (501), and a corner wrapping strip (503) surrounding and detachably fixed on the periphery of the top plate (502);

the supporting raft (501) comprises an outer frame (501a), a plurality of supporting beams (501b) transversely fixed in the outer frame (501a), and pins (501c) fixed at the bottom of the outer frame (501a) and capable of being inserted into top channels (D) of supporting columns (200);

the corner wrapping strip (503) is wrapped at the outer edges of the top plate (502) and the top of each supporting column (200), a second through hole (C-2) communicated into the channel (D) of the supporting column is formed in the outer side face of the top of each supporting column (200), a corresponding third through hole (C-3) is formed in the corner wrapping strip (503), a corresponding third screw hole (K-3) is formed in a pin (501C) inserted into the channel (D) in the top of each supporting column (200), the third through hole (C-3), the second through hole (C-2) and the third screw hole (K-3) are opposite to each other, and the third through hole (C-3), the second through hole (C-2) and the third screw hole (K-3) sequentially penetrate through the top.

6. The container type monitoring station for the integrated energy system according to claim 5, wherein: at least one part of the middle columns (202) is also provided with vertical inner wall fixing grooves (202b) on the other side surface except the side surface where the second outer wall fixing grooves (202a) are located, the openings of the inner wall fixing grooves (202b) face inwards, and the opening width is matched with the thickness of the wall panel splicing block (300).

7. The container type monitoring station for the integrated energy system according to any one of claims 1, 2, 4 or 6, wherein: the upper surface of the foundation plate (101a) is higher than the top surfaces of the joint rods (102) in vertical height, so that a height difference is formed, and the top surfaces of the joint rods (102) are consistent in height;

the foundation component (100) further comprises a support plate (103) covering the tops of all the connecting rods (102) and a floor (104) laid on the upper layer of the support plate (103); the thickness of backup pad (103) equals the difference in height between foundatin plate (101a) upper surface and joint pole (102) top surface, just the edge of backup pad (103) is seted up corresponding to the peripheral profile of foundatin plate (101a) dodges notch (103a), each foundatin plate (101a) can just be inlayed and dodge in notch (103a) that correspond respectively.

8. The container type monitoring station for the integrated energy system according to claim 7, wherein: also includes a stretching assembly (600) which is connected between the two base bases (101) at the diagonal corners in a cross way;

the stretching assembly (600) comprises a first pull rod (601), a second pull rod (602), a connecting piece (603) for connecting the inner ends of the first pull rod and the second pull rod, and a hand grip module (604) which is respectively arranged at the outer ends of the first pull rod and the second pull rod and can be detachably connected with the corner of the base plate (101 a); the hand grip modules (604) of the first pull rod (601) and the second pull rod (602) of the same stretching assembly (600) are respectively connected with a pair of base plates (101a) which are diagonally opposite to each other, and four corners of each base plate (101a) are respectively provided with connecting holes (101a-2) matched with the hand grip modules (604).

9. The container type monitoring station for the integrated energy system according to claim 8, wherein: the connecting piece (603) comprises a first connecting end (603a) integrally formed on the inner end of the first pull rod (601), a second connecting end (603b) integrally formed on the inner end of the second pull rod (602), and a locking ring (603c) sleeved on the periphery of the first connecting end (603 a);

the first connecting end (603a) is internally provided with a slide way (603a-1) with an opening at the end part, and the slide way (603a-1) is communicated with the outside through a seam (603a-2) with a side edge extending synchronously;

the second connecting end (603b) is matched with the slide way (603a-1) and inserted into the slide way, the end part of the second connecting end (603b) is hinged with a squeezing block (603b-1), the outer edge of the squeezing block (603b-1) is provided with a squeezing bulge (603b-2), the squeezing block (603b-1) is further fixed with a poking rod (603b-3) which extends out of the slide way (603a-1) from the seam (603a-2), and the tail end of the poking rod (603b-3) is provided with a limiting block (603 b-4);

when the poke rod (603b-3) is rotated and embedded into the slit (603a-2), the extrusion bulge (603b-2) can extrude the inner side wall of the slideway (603a-1) and can slide and limit the locking ring (603c) at the periphery of the poke rod (603 b-3).

10. The container type monitoring station for the integrated energy system according to claim 9, wherein: the gripper module (604) comprises a clamping plate (604a) integrally formed at the outer end of the first pull rod (601) or the second pull rod (602), a pair of clamping jaws (604b) crosswise arranged in the interlayer of the clamping plate (604a) and capable of relatively rotating, and a driving piece (604c) capable of driving the clamping jaws (604b) to relatively rotate so as to control the opening size of the outer end of the clamping jaws;

two clamping jaws (604b) are hinged at the tail end of the clamping plate (604a) through a first pin shaft (604d), and the outer ends of the two clamping jaws form a jaw; the clamping plate (604a) comprises a first strip plate (604a-1) and a second strip plate (604a-2) which are parallel to each other, the inner side walls of the first strip plate and the second strip plate are respectively provided with a sliding groove (H) which extends along the length direction of the gripper module (604), the outer side wall of the second strip plate (604a-2) is provided with a sliding seam (H-1) which is consistent with the trend of the sliding groove (H) and is communicated with the sliding groove (H), and the width of the sliding seam (H-1) is smaller than that of the sliding groove (H);

the driving piece (604c) comprises a pair of connecting pieces (604c-1) which are parallel to each other and can be respectively embedded into the two sliding grooves (H), a connecting column (604c-2) fixed between the connecting pieces (604c-1), and a pair of driving rods (604c-3) which are hinged to the outer ends of the connecting pieces (604c-1), and the tail ends of the two driving rods (604c-3) are respectively hinged to the inner ends of the two clamping jaws (604b) through second pin shafts (604 e);

a through fourth screw hole (K-4) is formed in the connecting column (604c-2), and a fourth bolt (S-4) is rotatably arranged in the fourth screw hole (K-4) in a penetrating manner; an elastic cable (604f) is connected between the inner ends of the two claws (604b), and the elastic cable (604f) bypasses the connecting column (604c-2) and is in a tensioning state under the tension of the connecting column (604 c-2).

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