CN216481184U - Heat pipe network structure capable of distributing flow evenly - Google Patents

Abstract

The utility model discloses a heat pipe network structure of evenly shunting, including the heating power body, the fixed bearing assembly who has evenly distributed that has cup jointed of lateral surface of heating power body, the outside end fixedly connected with dustcoat of bearing assembly, the spout has been seted up to the inboard relative wall of dustcoat, spout swing joint that the dustcoat was seted up has the motion subassembly, the lateral surface fixedly connected with evenly distributed's of heating power body shunt tubes, the terminal kneck of shunt tubes is all fixed the rubber circle that has cup jointed, the bearing assembly is including the endotheca, the endotheca cup joints with the lateral surface of heating power body is fixed, the lateral surface fixedly connected with evenly distributed's of endotheca loose axle, the spring has been cup jointed in the equal activity of loose axle, the unable relocation of heat supply output end that traditional heat pipe network structure had been solved to this heat pipe network structure leads to its problem that the flexibility can be low, thereby this heat pipe network has solved traditional heat pipe network structure and has not had a structure that can strengthen its bearing capacity and promote its life's problem .

Description

Heat pipe network structure capable of distributing flow evenly

Technical Field

The utility model relates to a heating power pipe network technical field, more specifically relate to a heat pipe network structure of even reposition of redundant personnel.

Background

The heat supply pipeline network is also called a heat supply pipeline, starts from a boiler room, a direct-fired machine room, a heat supply center and the like, leads a heat source to a heat supply pipeline of a building heat inlet, a plurality of heat supply pipelines form a pipe network, and heat energy can be transmitted to each household for use by using the heat supply pipe network.

The heat supply output end of the traditional heat pipe network structure in the prior art is usually in a fixed position, when the position of a user needing to use heat is changed, the structure of the original heat pipe network needs to be laid again, the process is relatively complex and inconvenient, namely, the position of the heat supply output end of the traditional heat pipe network structure cannot be changed, and the use flexibility is low.

The heat supply pipeline of traditional heat supply pipe network structure under prior art lays underground usually, and the heat supply pipeline that is located underground receives the pressure that soil and above-ground object brought for a long time, and the heat supply pipeline intensity of traditional heat supply pipe network structure is general, leads to the life of traditional heat supply pipe network structure to reduce easily under long-term pressure effect, thereby traditional heating power pipe network does not have the structure that can strengthen its bearing capacity to promote its life promptly.

SUMMERY OF THE UTILITY MODEL

In order to overcome the above-mentioned defect of prior art, the utility model provides a heat pipe network structure of even reposition of redundant personnel to solve the problem that exists among the above-mentioned background art.

The utility model provides a following technical scheme: the utility model provides a heat pipe network structure of even reposition of redundant personnel, includes the heating power body, still includes:

the pressure-bearing assembly: the outer side surface of the heating power pipe body is provided with a pressure-bearing assembly;

outer cover: the outer end of the pressure bearing assembly is provided with an outer cover;

a motion assembly: and a moving component is arranged on the inner side of the outer cover.

Further, the fixed pressure-bearing subassembly that has connect evenly distributed of lateral surface of heating power body, the outside end fixedly connected with dustcoat of pressure-bearing subassembly, the spout has been seted up to the relative wall in inboard of dustcoat, the spout swing joint that the dustcoat was seted up has the motion subassembly, the lateral surface fixedly connected with evenly distributed's shunt tubes of heating power body, the terminal kneck of shunt tubes all fixedly cup joints the rubber circle, and this is the overall structure overall arrangement of this evenly distributed's thermal power pipe network structure.

Further, the pressure-bearing assembly comprises an inner sleeve, the inner sleeve is fixedly sleeved with the outer side face of the heating power pipe body, the outer side face of the inner sleeve is fixedly connected with movable shafts which are uniformly distributed, springs are movably sleeved on the movable shafts, a pressure-bearing ring is movably sleeved on the outer side face of the inner sleeve, through holes which are uniformly distributed are formed in the outer side face of the pressure-bearing ring, the movable shafts are movably sleeved with the through holes which are formed in the pressure-bearing ring, connecting columns which are uniformly distributed are fixedly connected on the outer side face of the pressure-bearing ring, the tail ends of the connecting columns are fixedly connected with the inner side wall face of the outer cover, and the pressure-bearing capacity of the uniformly-divided heating power pipe network structure can be enhanced through the structure.

Further, the motion subassembly is including the slide, the spout swing joint that slide and dustcoat were seted up, the lateral surface fixedly connected with connecting plate of slide, connecting plate threaded connection has the lead screw, the axis body fixedly connected with driving motor's of lead screw output shaft, the solid fixed ring of the equal fixedly connected with in both ends of dustcoat, solid fixed ring's side and the fixed cup joint of driving motor, the fixed heat supply end pipe that has cup jointed of slide, the fixed go-between that has cup jointed of output of heat supply end pipe, the lateral surface threaded connection of go-between has evenly distributed's bolt, the position of the heat supply output of the heat pipe network structure of this evenly reposition of redundant personnel of change that can be nimble through this structure.

Further, the spacing distance between the bearing rings is equal, the number of the movable shafts on the same bearing ring is four, the number of the connecting columns on the same bearing ring is four, the installation angles between the movable shafts and the connecting columns are mutually diverged, when the heat pipe network structure with uniform flow distribution is pressed, pressure is transmitted to the outer cover, the spring is driven to apply pressure to the spring by the aid of the pressure-bearing ring, the spring deforms to enable the movable shafts to perform buffer motion on through holes formed in the pressure-bearing ring, and accordingly the pressure effect borne by the movable shafts can be relieved.

Further, the quantity of solid fixed ring is two, gu fixed ring connects with the fixed cover in both ends of heating power body respectively, driving motor and the mutual fixed connection of solid fixed ring of one end, the axis body end of lead screw cup joints with the solid fixed ring activity of the other end, and driving motor drive lead screw is rotatory, and the lead screw is rotatory to be driven the slide and to slide in the dustcoat to can change its heat supply position.

The utility model discloses a technological effect and advantage:

1. the utility model discloses be equipped with the motion subassembly, when this even reposition of redundant personnel's thermal power pipe network structure uses, when the user position of required use heating power changes, accessible driving motor drive lead screw is rotatory, the rotatory slide that drives of lead screw slides in the spout that the dustcoat was seted up, when the shunt tubes of heating supply end pipe and a certain required position aligns, insert the heating supply pipe in the heating supply end pipe and with shunt tubes interconnect, the rubber circle provides its sealed effect, rotatory bolt makes the go-between fixed with the heating supply pipe, just accomplish its heating supply port position change effect from this, the unable repositioning of heating output end of traditional thermal power pipe network structure has been solved through this structure, lead to the problem that its flexibility of use can be low.

2. The utility model discloses be equipped with the pressure-bearing subassembly, this evenly shunted heat pipe network structure lay with underground after, when it receives pressure, pressure at first transmits to the dustcoat, the dustcoat drives the bearing ring through the spliced pole and applys pressure to the spring this moment, the spring pressurized takes place to deform and makes the loose axle carry out the cushioning movement in the through-hole that the bearing ring was seted up, can effectively protect the pipeline heat supply structure of heating power body through this structure, thereby it does not have a structure that can strengthen its bearing capacity and promotes its life's problem to have solved traditional heat pipe network structure from this.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the structure of the heating tube of the present invention.

Fig. 3 is a schematic view of the structure of the shunt tube of the present invention.

Fig. 4 is a schematic structural view of the pressure-bearing assembly of the present invention.

Fig. 5 is a schematic structural diagram of the motion assembly of the present invention.

Fig. 6 is a schematic view of the structure of the slide plate of the present invention.

The reference signs are: 1. a thermal pipe body; 2. a pressure-bearing assembly; 201. an inner sleeve; 202. a movable shaft; 203. a spring; 204. a pressure-bearing ring; 205. connecting columns; 3. a housing; 4. a motion assembly; 401. a slide plate; 402. a connecting plate; 403. a lead screw; 404. a drive motor; 405. a fixing ring; 406. a heat supply end pipe; 407. a connecting ring; 408. a bolt; 5. a shunt tube; 6. a rubber ring.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the drawings in the present invention, and the forms of the structures described in the following embodiments are merely examples, and the present invention relates to a heat pipe network structure for uniform distribution of heat, which is not limited to the structures described in the following embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 and 2, the utility model provides a heat pipe network structure of even reposition of redundant personnel, including heating power body 1, still include:

the pressure bearing assembly 2: the outer side surface of the heating power pipe body 1 is provided with a pressure-bearing assembly 2;

the outer cover 3: the outer end of the pressure bearing component 2 is provided with an outer cover 3;

the moving assembly 4: the inner side of the housing 3 is provided with a moving assembly 4.

Referring to fig. 1 and 3, the fixed bearing assembly 2 that has connect evenly distributed of lateral surface of heating power body 1, the outside end fixedly connected with dustcoat 3 of bearing assembly 2, the spout has been seted up to the relative wall in dustcoat 3's inboard, the spout swing joint that dustcoat 3 was seted up has motion assembly 4, the lateral surface fixedly connected with evenly distributed's of heating power body 1 shunt tubes 5, the terminal kneck of shunt tubes 5 is all fixed the rubber circle 6 that has cup jointed, this is the overall structure overall arrangement of this heat pipe network structure of evenly shunting.

Referring to fig. 4, the pressure-bearing assembly 2 includes an inner sleeve 201, the inner sleeve 201 is fixedly sleeved with the outer side surface of the heat power tube body 1, the outer side surface of the inner sleeve 201 is fixedly connected with movable shafts 202 which are uniformly distributed, the movable shafts 202 are movably sleeved with springs 203, the outer side surface of the inner sleeve 201 is movably sleeved with a pressure-bearing ring 204, the outer side surface of the pressure-bearing ring 204 is provided with through holes which are uniformly distributed, the movable shafts 202 are movably sleeved with the through holes which are provided by the pressure-bearing ring 204, the outer side surface of the pressure-bearing ring 204 is fixedly connected with connecting columns 205 which are uniformly distributed, the tail ends of the connecting columns 205 are fixedly connected with the inner side wall surface of the outer cover 3, when the outer cover receives pressure, the pressure is firstly transmitted to the outer cover 3, at this time, the outer cover 3 drives the pressure-bearing ring 204 to apply pressure to the springs 203 to deform, so that the movable shafts 202 perform buffering motion in the through holes which are provided by the pressure-bearing ring 204.

Referring to fig. 5 and 6, the moving assembly 4 includes a sliding plate 401, the sliding plate 401 is movably connected to a sliding slot defined in the housing 3, a connecting plate 402 is fixedly connected to an outer side surface of the sliding plate 401, the connecting plate 402 is connected to a screw 403 through a thread, an output shaft of a driving motor 404 is fixedly connected to a shaft body of the screw 403, fixing rings 405 are fixedly connected to both ends of the housing 3, a side surface of each fixing ring 405 is fixedly sleeved to the driving motor 404, a heat supply end pipe 406 is fixedly sleeved to the sliding plate 401, a connecting ring 407 is fixedly sleeved to an output end of the heat supply end pipe 406, bolts 408 are uniformly distributed and threadedly connected to an outer side surface of the connecting ring 407, the screw 403 is driven to rotate by the driving motor 404, the screw 403 rotates to drive the sliding plate 401 to slide in the sliding slot defined in the housing 3, when the heat supply end pipe 406 is aligned to a shunt pipe 5 at a desired position, the heat supply pipe is inserted into the heat supply end pipe 406 and is engaged with the shunt pipe 5, the rubber ring 6 provides its sealing effect and the bolt 408 is rotated to make the connection ring 407 fix the heating pipe, thereby accomplishing its heating port position changing effect.

Referring to fig. 2 and 4, the distance between the pressure rings 204 is equal, the number of the movable shafts 202 on the same pressure ring 204 is four, the number of the connection columns 205 on the same pressure ring 204 is four, and the installation angles between the movable shafts 202 and the connection columns 205 are mutually diverged, when the evenly-divided heat pipe network structure is pressed, the pressure is transmitted to the outer cover 3, at this time, the pressure ring 204 is driven to apply pressure to the spring 203, and the spring 203 deforms to enable the movable shafts 202 to perform buffering motion on the through holes formed in the pressure ring 204, so that the pressure effect borne by the springs can be relieved.

Referring to fig. 5, the number of the fixing rings 405 is two, the fixing rings 405 are respectively fixedly sleeved on two ends of the heat distribution pipe body 1, the driving motor 404 is fixedly connected with the fixing ring 405 on one end, the end of the shaft body of the lead screw 403 is movably sleeved on the fixing ring 405 on the other end, the driving motor 404 drives the lead screw 403 to rotate, and the lead screw 403 rotates to drive the sliding plate 401 to slide in the outer cover 3, so that the heat supply position of the sliding plate can be changed.

The utility model discloses a theory of operation: when the evenly-divided heat pipe network structure is used, when the position of a user needing heat is changed, the lead screw 403 can be driven to rotate by the driving motor 404, the lead screw 403 rotates to drive the sliding plate 401 to slide in a sliding groove formed in the outer cover 3, when the heat supply end pipe 406 is aligned with a shunt pipe 5 at a certain required position, the heat supply pipe is inserted into the heat supply end pipe 406 and is mutually jointed with the shunt pipe 5, the rubber ring 6 provides a sealing effect, the bolt 408 is rotated to fix the heat supply pipe by the connecting ring 407, so that the position change effect of a heat supply port is completed, after the evenly-divided heat pipe network structure is laid and underground, when the heat supply pipe network structure is subjected to pressure, the pressure is firstly transmitted to the outer cover 3, at the moment, the outer cover 3 drives the pressure bearing ring 204 to apply pressure to the spring 203 through the connecting column 205, the spring 203 is pressed and deformed to enable the movable shaft 202 to perform buffering motion in a through hole formed in the pressure bearing ring 204, the pipeline heat supply structure of the heat pipe body 1 can be effectively protected through the structure, and therefore one-time work flow of the heat pipe network structure capable of uniformly distributing the flow is completed.

The points to be finally explained are: first, in the description of the present application, it should be noted that, unless otherwise specified and limited, the terms "mounted," "connected," "connecting," and "connecting" should be understood broadly, and may be a mechanical connection or an electrical connection, or a communication between two elements, and may be directly connected, and "upper," "lower," "left," and "right" are only used to indicate relative positional relationships, and when the absolute position of the object to be described is changed, the relative positional relationships may be changed;

secondly, the method comprises the following steps: in the drawings of the disclosed embodiments of the present invention, only the structures related to the disclosed embodiments are referred to, and other structures can refer to the common design, and under the condition of no conflict, the same embodiment and different embodiments of the present invention can be combined with each other;

and finally: the above description is only for the preferred embodiment of the present invention and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a heat pipe network structure of even reposition of redundant personnel, includes heating power body (1), its characterized in that still includes:

pressure-bearing assembly (2): a pressure-bearing assembly (2) is arranged on the outer side surface of the heating power pipe body (1);

outer cover (3): an outer cover (3) is arranged at the outer end of the pressure bearing assembly (2);

moving assembly (4): the inner side of the outer cover (3) is provided with a moving component (4).

2. The evenly distributed heat pipe network structure according to claim 1, wherein: the outer side face of the heating power pipe body (1) is fixedly sleeved with a pressure-bearing assembly (2) which is uniformly distributed, the outer side end of the pressure-bearing assembly (2) is fixedly connected with an outer cover (3), the inner side wall face of the outer cover (3) is opposite to the wall face, a sliding groove is movably connected with a movement assembly (4) which is arranged on the outer cover (3), the outer side face of the heating power pipe body (1) is fixedly connected with shunt pipes (5) which are uniformly distributed, and rubber rings (6) are fixedly sleeved at the end connector of the shunt pipes (5).

3. The evenly distributed heat pipe network structure according to claim 2, wherein: pressure-bearing subassembly (2) including endotheca (201), endotheca (201) and the fixed cup joint of the lateral surface of heating power body (1), lateral surface fixedly connected with evenly distributed's loose axle (202) of endotheca (201), spring (203) have all been cup jointed in the activity of loose axle (202), bearing ring (204) have been cup jointed in the lateral surface activity of endotheca (201), evenly distributed's through-hole has been seted up to the lateral surface of bearing ring (204), through-hole activity that the loose axle (202) all seted up with bearing ring (204) is cup jointed, the lateral surface fixedly connected with evenly distributed's spliced pole (205) of bearing ring (204), the end of spliced pole (205) all with the inside wall fixed connection of dustcoat (3).

4. The evenly distributed heat pipe network structure according to claim 2, wherein: motion subassembly (4) including slide (401), the spout swing joint that slide (401) and dustcoat (3) were seted up, lateral surface fixedly connected with connecting plate (402) of slide (401), connecting plate (402) threaded connection has lead screw (403), the output shaft of the axis body fixedly connected with driving motor (404) of lead screw (403), the solid fixed ring (405) of the equal fixedly connected with in both ends of dustcoat (3), the side and the fixed cup joint of driving motor (404) of solid fixed ring (405), slide (401) are fixed to have cup jointed heat supply end pipe (406), the fixed cover of output of heat supply end pipe (406) has connect go-between (407), the lateral surface threaded connection of go-between (407) has evenly distributed's bolt (408).

5. A uniformly divided heat pipe network structure according to claim 3, wherein: the spacing distance between the bearing rings (204) is equal, the number of the movable shafts (202) on the same bearing ring (204) is four, the number of the connecting columns (205) on the same bearing ring (204) is four, and the installation angles between the movable shafts (202) and the connecting columns (205) are mutually diverged.

6. The evenly distributed heat pipe network structure according to claim 4, wherein: the quantity of solid fixed ring (405) is two, gu fixed ring (405) connect with the fixed cover in both ends of heating power body (1) respectively, driving motor (404) and the solid fixed ring (405) mutual fixed connection of one end, the axis body end of lead screw (403) is cup jointed with solid fixed ring (405) activity of the other end.

Images