CN219825697U - A embedded pipe wall for assembled building - Google Patents

Abstract

The utility model discloses an embedded pipe wall body for an assembled building, which relates to the technical field of buildings, wherein embedded pipes are laid in the embedded pipe wall body and fixedly connected with vertical structural steel bars of the embedded pipe wall body through embedded pipe positioners; the embedded pipe positioner comprises a positioning pipe, a pipe embedding positioning piece and a connecting piece; the positioning pipe is fixedly connected to the vertical structural steel bar through a connecting piece; the positioning pipe is fixedly connected with a pipe embedding positioning piece; the embedded pipe locating piece is used for fixedly connecting the embedded pipe. A control box and a connecting box are also arranged in the embedded pipe wall body; the control box is connected with the connecting box through a water supply branch pipe and a water return branch pipe, and the control box is connected with the connecting box between adjacent embedded pipe walls. The utility model designs the embedded pipe positioner to solve the problem of positioning the embedded pipe in the die; the control box and the connecting box are designed to solve the problem of connection of pipelines between walls during installation; the whole wall structure is prefabricated and processed in factories, so that wet operation on a construction site is avoided.

Description

A embedded pipe wall for assembled building

Technical Field

The utility model relates to the technical field of buildings, in particular to an embedded pipe wall body for an assembled building.

Background

The production process of the traditional prefabricated concrete assembled wall body is integrated, so that components in the wall body need to be positioned in a die in advance. In general practice, the structural rebars need to be tied and installed prior to casting the concrete. And (3) binding the pipeline on a wire mesh in advance before cast-in-situ, placing the pipeline into a wall, and pouring cement mortar to form the complete wall. The prefabricated concrete wall body needs to ensure the positions of the embedded parts, the embedded bars and the internal heat insulation layer during construction, and the manual pipeline bundling on the steel wire net is time-consuming and labor-consuming, the positioning of the pipeline cannot be controlled, and the precision is difficult to ensure. In addition, precast concrete wall panels are prefabricated in advance at a factory to be assembled on site. The embedded pipe wall technology is applied to the precast concrete wall, and the problem of how to connect the pipeline wall with the wall and how to connect the wall with the floor is inevitably considered in the design stage. And when the connection of the pipelines needs a certain precision to ensure the on-site splicing components, the pipelines between the components can be accurately connected, so that errors are avoided.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides an embedded pipe wall body for an assembled building, and an embedded pipe positioner is designed to solve the problem of positioning an embedded pipe in a die; the whole wall structure is prefabricated and processed in factories, so that wet operation on a construction site is avoided.

In order to achieve the above purpose, the present utility model adopts the following technical scheme, including:

an embedded pipe wall body for an assembled building, wherein an embedded pipe is laid in the embedded pipe wall body; the embedded pipe is fixedly connected with a vertical structural steel bar of the embedded pipe wall body through an embedded pipe positioner;

the embedded pipe positioner includes: a positioning rod, a pipe embedding positioning piece and a connecting piece; the positioning rod is fixedly connected to the vertical structural steel bars through the connecting piece; the positioning rod is fixedly connected with a pipe embedding positioning piece; the embedded pipe locating piece is used for fixedly connecting the embedded pipe.

Preferably, the connecting piece comprises a connecting ring and a connecting rod; the connecting ring is used for being sleeved on the vertical structural steel bars, and the connecting rod is used for being inserted into the positioning rod.

Preferably, the embedded pipe positioning piece comprises a positioning ring and an opening ring, wherein the positioning ring is used for being sleeved on the positioning rod, and the opening ring is used for being clamped with the embedded pipe.

Preferably, the positioning rod is provided with a chute along the length direction of the rod; the positioning rod is also provided with a positioning hole; the inner wall of the positioning ring of the embedded pipe positioning piece is provided with a lug matched with the chute and used for sliding along the chute; the inner wall of the positioning ring of the embedded pipe positioning piece is also provided with a telescopic bulge structure matched with the positioning hole and used for being fixedly connected with the positioning hole.

Preferably, a control box and a connecting box are arranged in the embedded pipe wall body; a wall water supply pipe and a wall water return pipe are arranged in the control box; a water inlet connecting pipe and a water return connecting pipe are arranged in the connecting box;

the water supply inlet of the wall water supply pipe is connected with the outlet of the water inlet connecting pipe of the connecting box through a water supply branch pipe; the backwater outlet of the wall backwater pipe is connected with the inlet of a backwater connecting pipe of the connecting box through a backwater branch pipe;

the side wall of the shell of the embedded pipe wall body is provided with a through hole for connecting the outlet of the backwater connecting pipe and the inlet of the water inlet connecting pipe outwards;

the wall water supply pipe is connected with the water inlet of the embedded pipe through the first water supply pipe; the wall return pipe is connected with the water outlet of the embedded pipe through the first return pipe.

Preferably, the control box is used for controlling the input and output of the embedded pipe in the embedded pipe wall body; the first water supply pipe is provided with a thermometer, a thermal actuator and a flowmeter; and a thermometer and a stop valve are arranged on the first water return pipe.

Preferably, the side wall of the shell of the embedded pipe wall body is also provided with a through hole for connecting a second water supply outlet of the wall water supply pipe and a second water return inlet of the wall water return pipe outwards;

and a second water supply outlet of the wall water supply pipe is connected with an inlet of a water inlet connecting pipe in the adjacent embedded pipe wall body, and a second water return inlet of the wall water return pipe is connected with an outlet of a water return connecting pipe in the adjacent embedded pipe wall body.

The utility model has the advantages that:

(1) The embedded pipe positioner is designed in the embedded pipe wall body, so that the problem of positioning the embedded pipe in a die is solved. The problem that the traditional embedded pipe wall technology needs secondary construction is solved, the whole wall structure is prefabricated and processed in a factory, and wet operation on a construction site is avoided.

(2) The control box and the connecting box are designed in the embedded pipe wall body, so that the construction positioning problem caused by the combination of the embedded pipe wall technology and the fabricated precast concrete wall body technology is solved, and the pipeline connection problem during installation is solved. The control box can play the embedded pipeline end of accurate positioning in the time of the construction structurally, and accurate counterpoint effect between two adjacent walls when on-the-spot installation can hold and protect equipment such as sensor in addition, is convenient for later maintenance. The design of the connecting box solves the positioning problem of the embedded pipeline during construction, and provides an operation space for fusion connection of adjacent wall pipelines during installation.

(3) The embedded pipes are paved in the embedded pipe wall body, and the wall body can be heated or cooled by inputting circulating hot water or circulating cold water into the embedded pipes, so that indoor temperature regulation control is realized.

(4) The control box is integrated with the actuator and the sensor, so that the input and the output of the embedded pipe in the embedded pipe wall body are controlled, the flow control and the temperature monitoring of the single wall body can be realized, and the temperature control of the single wall body is realized.

(5) The integrated embedded pipe wall body greatly reduces the thickness of the traditional embedded pipe wall body, and changes the direction to increase the indoor use area.

(6) The embedded pipe positioner disclosed by the utility model is completely connected by adopting a tool-free quick connection, so that the installation accuracy is ensured, and the installation flow is simplified.

(7) The embedded pipe positioner adopts a multi-position fool-proof design, avoids the possibility of error operation in the installation process, reduces the alignment time and improves the installation efficiency.

Drawings

Fig. 1 is a schematic view of an embedded pipe wall for an assembled building in a disassembled state.

Fig. 2 is a schematic diagram of connection between a control box and a connection box in an embedded pipe wall.

FIG. 3 is a schematic diagram of a control box housing in an embedded pipe wall.

Fig. 4 is a schematic view of a junction box housing in an embedded pipe wall.

FIG. 5 is a schematic illustration of the connection of an embedded tube to an embedded tube positioner.

FIG. 6 is a schematic view of a connector in an in-line tubing locator.

FIG. 7 is a schematic view of a tube-in-tube retainer in a tube-in-tube retainer.

FIG. 8 is a second schematic view of a tube-in-tube retainer in a tube-in-tube retainer.

Fig. 9 is a schematic view of a locating lever in an in-line pipe locator.

Reference numerals illustrate:

4-embedded pipe walls, 7-control boxes, 8-connecting boxes and 9-embedded pipes;

41-embedded pipe positioners, 42-structural reinforcing steel bars, 43-shells, 411-positioning rods, 412-embedded pipe positioners, 413-connecting pieces, 4111-sliding grooves, 4112 positioning holes, 4121-positioning rings, 4122-split rings, 4131-connecting rings and 4132-connecting rods;

51-thermometer, 52-thermal actuator, 53-flowmeter, 54-stop valve;

71-wall water supply pipe, 72-wall return pipe, 711-water supply inlet, 712-first water supply pipe, 713-second water supply outlet, 721-return water outlet, 722-first return pipe, 723-second return water inlet;

81-water inlet connecting pipe, 82-water return connecting pipe, 811-inlet connecting pipe inlet, 812-water inlet connecting pipe outlet, 821-water return connecting pipe outlet, 822-water return connecting pipe inlet.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1, an embedded pipe wall body for an assembled building of this embodiment is provided with a control box 7, a connection box 8 and an embedded pipe 9 in the embedded pipe wall body 4.

A wall water supply pipe 71 and a wall water return pipe 72 are arranged in the control box 7; a water inlet connecting pipe 81 and a water return connecting pipe 82 are arranged in the connecting box 8; the control box 7 is connected with the connecting box 8 through a water supply branch pipe and a water return branch pipe.

As shown in fig. 1 and 2, the side wall of the casing 43 of the embedded pipe wall 4 is provided with a through hole, which is used for the outward connection of the second water supply outlet 713 of the wall water supply pipe 71 and the second water return inlet 723 of the wall water return pipe 72, and for the outward connection of the outlet 821 of the water return connection pipe 82 and the inlet 811 of the water inlet connection pipe 81.

As shown in fig. 1 and 2, the water supply inlet 711 of the wall water supply pipe 71 is connected to the outlet 812 of the water inlet connection pipe 81 of the connection box 8 through a water supply branch pipe; the wall water supply pipe 71 is connected with the water inlet of the embedded pipe 9 through a first water supply pipe 712; the backwater outlet 721 of the wall backwater pipe 72 is connected with the inlet 822 of the backwater connecting pipe 82 of the connecting box 8 through a backwater branch pipe; the wall return pipe 72 is connected to the water outlet of the embedded pipe 9 through a first return pipe 722.

In this embodiment, the design of the casing of the control box 7 is as shown in fig. 3, and through holes on the bottom wall and the side wall of the casing of the control box 7 are used for the outward connection of the wall water supply pipe 71 and the wall water return pipe 72. The design of the shell of the connection box 8 is shown in fig. 4, and through holes on the side wall of the shell of the connection box 8 are used for outward connection of a water inlet connection pipe 81 and a water return connection pipe 82.

As shown in fig. 2, the first water supply pipe 712 is provided with a thermometer 51, a thermal actuator 52, and a flowmeter 53; the first return pipe 722 is provided with a thermometer 51 and a shutoff valve 54. The thermal actuator 52 is composed of a temperature controller, a valve actuator and a valve, and the working principle is as follows: if the indoor temperature rises and reaches the temperature set by the temperature controller, the positive thermistor in the thermal actuator 52 starts to work, and the thermal expansion device is heated to close the valve; if the indoor temperature is reduced and is lower than the temperature set by the temperature controller, the temperature controller is disconnected, the thermal actuator 52 cools, the expansion device contracts, and the valve is opened.

As shown in fig. 5, the embedded pipe 9 is fixedly connected with a vertical structural steel bar 42 of the embedded pipe wall body 4 through an embedded pipe positioner 41. The in-line pipe positioner 41 includes: a positioning rod 411, a pipe embedding positioning piece 412 and a connecting piece 413. The embedded pipe locating piece 412 is used for fixing the embedded pipe 9, the locating rod 411 is used for fixing the embedded pipe locating piece 412, and the locating rod 411 is fixedly connected to the vertical structural steel bar 42 through the connecting piece 413.

As shown in fig. 6, the connecting member 413 includes a connecting ring 4131 and a connecting rod 4132; the connecting ring 4131 is used to be sleeved on the vertical structural steel bars 42, and the connecting rod 4132 is used to be inserted into the positioning rod 411.

As shown in fig. 7 and 8, the tube inserting positioning member 412 includes a positioning ring 4121 and a split ring 4122, the positioning ring 4121 is used to be sleeved on the positioning rod 411, and a telescopic protrusion structure is provided in the positioning ring 4121. The split ring 4122 is used to engage the inner tube 9. In embodiment 2, two types of pipe-inserting positioning members 412 are shown in fig. 7 and 8, which are different in the circumferential direction of the split ring 4122 for clamping the pipe-inserting 9 in different directions.

As shown in fig. 9, the positioning rod 411 is provided with a chute 4111 along the length direction of the rod; the positioning rod 411 is also provided with a positioning hole 4112; the protrusion on the inner wall of the positioning ring 4121 of the tube inserting positioning member 412 slides on the positioning rod 411 along the sliding groove 4111, and slides to the corresponding positioning hole 4112, the telescopic protrusion is inserted into the positioning hole 4112, and the positioning ring 4121 is fixedly connected with the positioning rod 411 through the telescopic protrusion and the positioning hole 4112.

The protrusion is hemispherical, and is clamped in the positioning hole 4112, but not locked in the positioning hole 4112, and is pushed inward with force to separate from the front positioning hole 4112 until the protrusion is pushed inward until the target positioning hole 4112, and the positioning locking force between the protrusion and the positioning hole 4112 is not very large because the embedded pipe 9 is not stressed in the right-left direction.

The construction process of the embedded pipe wall body for the fabricated building is as follows:

s1, determining the structure, pipe diameter, spacing and arrangement mode of the embedded pipe 9;

s2, determining the positions of a control box 7, a connecting box 8, a water supply branch pipe and a water return branch pipe according to a building design drawing, and drawing a construction drawing;

s3, fixing the control box 7 and the connection box 8 to the corresponding positions of the die according to the drawing;

s4, sleeving the positioning ring 4121 of the pipe embedding positioning piece 412 with the corresponding specification into the corresponding position of the positioning rod 411, wherein when the pipe embedding positioning piece is installed, the convex blocks on the inner wall of the positioning ring 4121 slide on the positioning rod 411 along the sliding grooves 4111 on the positioning rod 411 and slide to the corresponding positioning holes 4112 on the positioning rod 411, and the positions of the positioning holes 4112 are fixedly connected through telescopic bulges;

s5, connecting rods 4132 of the connecting piece 413 are broken away from the center seam, and connecting rings 4131 of the connecting piece 413 are sleeved into the vertical structural steel bars 42;

s6, inserting the end heads of the connecting rods 4132 of the connecting piece 413 into the end heads of the positioning rods 411 which are installed in the step S4, and ensuring the slot positions of the two end heads to be aligned and inserted;

s7, installing all the positioning rods 411, the pipe embedding positioning pieces 412 and the connecting pieces 413 by using the method;

s8, after the installation of the embedded pipe positioner 41 is completed, the embedded pipe 9 is clamped into the split ring 4122 of the embedded pipe positioner 412 according to the drawing requirements for fixation;

s9, connecting a water inlet end and a water outlet end of the embedded pipeline 9 with a first water supply pipe 712 of the wall water supply pipe 71 and a first water return pipe 722 of the wall water return pipe 72 of the control box 7 respectively;

s10, connecting a water supply inlet 711 of a wall water supply pipe 71 of the control box 7 with an outlet 812 of a water inlet connecting pipe 81 of the connecting box 8 through a water supply branch pipe; the backwater outlet 721 of the wall backwater pipe 72 of the control box 7 is connected with the inlet 822 of the backwater connecting pipe 82 of the connecting box 8 through a backwater branch pipe;

s11, the second water supply outlet 713 of the wall water supply pipe 71 and the second water return inlet 723 of the wall water return pipe 72 of the control box 7 are penetrated out through the through holes on the two side walls of the shell 43 of the embedded pipe wall body 4, and the inlet 811 of the water inlet connecting pipe 81 and the outlet 821 of the water return connecting pipe 82 of the connecting box 8 are penetrated out.

S12, the second water supply outlet 713 of the wall water supply pipe 71 and the second water return inlet 723 of the wall water return pipe 72 of the control box 7 are respectively connected with the inlet 811 of the water inlet connecting pipe 81 and the outlet 821 of the water return connecting pipe 82 of the connection box 8 in the adjacent embedded pipe wall 4.

The above embodiments are merely preferred embodiments of the present utility model and are not intended to limit the present utility model, and any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model should be included in the scope of the present utility model.

Claims (7)

1. An embedded pipe wall body for an assembled building is characterized in that an embedded pipe (9) is laid in the embedded pipe wall body (4); the embedded pipe (9) is fixedly connected with a vertical structural steel bar (42) of the embedded pipe wall body (4) through an embedded pipe positioner (41);

the in-line pipe positioner (41) includes: a positioning rod (411), a pipe embedding positioning piece (412) and a connecting piece (413); the positioning rod (411) is fixedly connected to the vertical structural steel bar (42) through a connecting piece (413); the positioning rod (411) is fixedly connected with a tube embedding positioning piece (412); the embedded pipe locating piece (412) is used for fixedly connecting the embedded pipe (9).

2. An in-line pipe wall for fabricated buildings according to claim 1, wherein the connection (413) comprises a connection ring (4131) and a connection rod (4132); the connecting ring (4131) is used for being sleeved on the vertical structural steel bars (42), and the connecting rod (4132) is used for being inserted into the positioning rod (411).

3. The embedded pipe wall for the fabricated building according to claim 1, wherein the embedded pipe positioning piece (412) comprises a positioning ring (4121) and a split ring (4122), the positioning ring (4121) is used for being sleeved on the positioning rod (411), and the split ring (4122) is used for being clamped with the embedded pipe (9).

4. The embedded pipe wall for the fabricated building according to claim 1, wherein the positioning rod (411) is provided with a sliding groove (4111) along the length direction of the rod; a positioning hole (4112) is formed in the positioning rod (411); the inner wall of the positioning ring (4121) of the embedded pipe positioning piece (412) is provided with a lug matched with the sliding groove (4111) for sliding along the sliding groove (4111); the inner wall of the positioning ring (4121) of the embedded pipe positioning piece (412) is also provided with a telescopic bulge structure matched with the positioning hole (4112) and used for being fixedly connected with the positioning hole (4112).

5. The embedded pipe wall body for the fabricated building according to claim 1, wherein a control box (7) and a connecting box (8) are arranged in the embedded pipe wall body (4); a wall water supply pipe (71) and a wall water return pipe (72) are arranged in the control box (7); a water inlet connecting pipe (81) and a water return connecting pipe (82) are arranged in the connecting box (8);

the water supply inlet (711) of the wall water supply pipe (71) is connected with the outlet (812) of the water inlet connecting pipe (81) of the connecting box (8) through a water supply branch pipe; a backwater outlet (721) of the wall backwater pipe (72) is connected with an inlet (822) of a backwater connecting pipe (82) of the connecting box (8) through a backwater branch pipe;

the side wall of the shell (43) of the embedded pipe wall body (4) is provided with a through hole for connecting an outlet (821) of the backwater connecting pipe (82) and an inlet (811) of the water inlet connecting pipe (81) outwards;

the wall water supply pipe (71) is connected with the water inlet of the embedded pipe (9) through a first water supply pipe (712); the wall return pipe (72) is connected with the water outlet of the embedded pipe (9) through the first return pipe (722).

6. An embedded pipe wall for an assembled building according to claim 5, wherein the control box (7) is used for controlling the input and output of an embedded pipe (9) in the embedded pipe wall (4); a thermometer (51), a thermal actuator (52) and a flowmeter (53) are arranged on the first water supply pipe (712); the first water return pipe (722) is provided with a thermometer (51) and a stop valve (54).

7. The embedded pipe wall for the fabricated building according to claim 5, wherein the side wall of the housing (43) of the embedded pipe wall (4) is further provided with a through hole for connecting the second water supply outlet (713) of the wall water supply pipe (71) and the second water return inlet (723) of the wall water return pipe (72) outwards;

between two adjacent embedded pipe walls (4), a second water supply outlet (713) of the wall water supply pipe (71) is connected with an inlet (811) of a water inlet connecting pipe (81) in the adjacent embedded pipe wall (4), and a second water return inlet (723) of the wall water return pipe (72) is connected with an outlet (821) of a water return connecting pipe (82) in the adjacent embedded pipe wall (4).