CN213514339U - Sensor mounting structure for intelligent building temperature control system - Google Patents

Abstract

The utility model discloses an intelligence building sensor mounting structure for temperature control system, including sensor body and fixed plate, the one end lateral wall fixedly connected with cylinder of sensor body, the first pinion rack of cylindrical upper end fixedly connected with, cylindrical lower extreme is equipped with first stop gear, the lateral wall fixedly connected with and cylinder assorted sleeve of fixed plate, the lower extreme fixedly connected with rectangular plate of second pinion rack, be equipped with second stop gear between rectangular plate and two magnetic paths, be equipped with two buffer gear between wall body and the fixed plate. The utility model discloses, rational in infrastructure, with the sensor body to pushing away, accomplish the installation of sensor, pull the sensor body backward, under T magnetic path and two magnetic path combined action, accomplish the dismantlement of sensor, and the installation is all simple with the dismantlement, brings the convenience for the staff.

Description

Sensor mounting structure for intelligent building temperature control system

Technical Field

The utility model relates to an intelligence building technical field especially relates to an intelligence building sensor mounting structure for temperature control system.

Background

The intelligent building optimally combines the structure, system, service and management of the building according to the requirements of users, thereby providing an efficient, comfortable and convenient humanized building environment for the users. The intelligent building is a product integrating modern science and technology. The technical foundation mainly comprises modern building technology, modern computer technology, modern communication technology and modern control technology.

Traditional intelligence building control by temperature change sensor all installs on wall or some fixed object usually, all punches in advance and installs fixedly through the screw again, is more troublesome, waste time and energy to its installation, not only influences the normal use of sensor, also is very inconvenient when needs are dismantled and are changed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcoming that exists among the prior art, and the sensor mounting structure for intelligent building temperature control system that proposes, it is with the sensor body to pushing away, accomplishes the installation of sensor, pulls the sensor body backward, under T magnetic path and two magnetic path combined action, accomplishes the dismantlement of sensor, and the installation is all simple with the dismantlement, brings the convenience for the staff.

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

a sensor mounting structure for an intelligent building temperature control system comprises a sensor body and a fixed plate, wherein a cylinder is fixedly connected to one end side wall of the sensor body, a first toothed plate is fixedly connected to the upper end of the cylinder, a first limiting mechanism is arranged at the lower end of the cylinder, a sleeve matched with the cylinder is fixedly connected to the side wall of the fixed plate, a rectangular groove is arranged at the upper end of the sleeve in a penetrating mode, a dead slot is formed in the lower end of the sleeve, two relative magnetic blocks are fixedly connected to the inner wall of the dead slot, a T-shaped groove is formed in the fixed plate, a second toothed plate is slidably connected to the inner wall of the T-shaped groove, a fixed block is fixedly connected to the upper end of the fixed plate, a rotating rod is rotatably connected to the fixed block, a first gear meshed with the second toothed plate and a second gear far away from the second toothed plate are fixedly, the lower extreme fixedly connected with long slab of second pinion rack, be equipped with second stop gear between long slab and two magnetic paths, fixed plate and telescopic one end are connected with wall body fixed connection jointly, be equipped with two buffer gear between wall body and the fixed plate.

Preferably, first stop gear includes the spacing groove on the cylinder, the inner wall fixedly connected with first spring of spacing groove, the other end fixedly connected with stopper of first spring, the inner wall sliding connection of stopper and spacing groove.

Preferably, the second limiting mechanism comprises a telescopic rod fixed at the upper end of the long plate, a second spring is sleeved on the telescopic rod, and the upper ends of the second spring and the telescopic rod are fixedly connected with a T-shaped magnetic block together.

Preferably, buffer gear includes the first L shaped plate with the lower extreme fixed connection of fixed plate, the lateral wall fixedly connected with second L shaped plate of wall body, two third springs of fixedly connected with between first L shaped plate and the second L shaped plate.

Preferably, the gear teeth on the first toothed plate are indirectly distributed, and the first toothed plate and the second gear are meshed with each other.

Preferably, the T magnetic block is matched with the empty slot, and the magnetic poles of the T magnetic block and the two magnetic blocks are different.

Compared with the prior art, the utility model, its beneficial effect does:

1. the staff pushes away the sensor body forward, when the stopper card of cylinder lower extreme arrived the dead slot, can accomplish the sensor installation promptly, promotes the sensor body once more, makes T magnetic path card to the dead slot in, and T magnetic path extrusion stopper makes the stopper slide the spacing inslot, later pulls backward, and T magnetic path breaks away from the dead slot, accomplishes the dismantlement of sensor body.

2. When the sensor works, the two third springs play a certain buffering effect on the sensor under the limiting of the first L-shaped plate and the second L-shaped plate.

To sum up, with the sensor body to pushing away, accomplish the installation of sensor, pull the sensor body backward, under T magnetic path and two magnetic paths combined action, accomplish the dismantlement of sensor, and the installation is all simple with the dismantlement, brings the convenience for the staff.

Drawings

Fig. 1 is a schematic structural view of a sensor mounting structure for an intelligent building temperature control system according to the present invention;

fig. 2 is a side view of the sensor mounting structure for an intelligent building temperature control system provided by the present invention;

fig. 3 is a top view of a second toothed plate in the sensor mounting structure for an intelligent building temperature control system provided by the present invention;

FIG. 4 is an enlarged view of the structure at A in FIG. 1;

fig. 5 is an enlarged view of the structure at B in fig. 1.

In the figure: 1 sensor body, 2 spacing grooves, 3 cylinders, 4 first pinion racks, 5 fixed plates, 6 fixed blocks, 7T-shaped grooves, 8 second gears, 9 dwang, 10 first gears, 11 wall bodies, 12 sleeves, 13 second pinion racks, 14 long plates, 15 telescopic links, 16T magnetic path, 17 second springs, 18 first L-shaped plates, 19 second L-shaped plates, 20 third springs, 21 limiting blocks, 22 first springs, 23 magnetic paths, 24 rectangular grooves, 25 empty grooves.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-5, an intelligence building sensor mounting structure for temperature control system, including sensor body 1 and fixed plate 5, the one end lateral wall fixedly connected with cylinder 3 of sensor body 1, the first pinion rack 4 of upper end fixedly connected with of cylinder 3, the gear tooth on the first pinion rack 4 is indirectness and distributes, first pinion rack 4 and 8 intermeshing of second gear, the lower extreme of cylinder 3 is equipped with first stop gear, first stop gear includes spacing groove 2 on the cylinder 3, the first spring 22 of inner wall fixedly connected with of spacing groove 2, the other end fixedly connected with stopper 21 of first spring 22, stopper 21 and the inner wall sliding connection of spacing groove 2, stopper 21 can slide to the spacing inslot 2.

Lateral wall fixedly connected with and 3 assorted sleeves 12 of cylinder of fixed plate 5, the upper end of sleeve 12 is run through and is equipped with rectangular channel 24, the lower extreme of sleeve 12 is equipped with dead slot 25, two relative magnetic path 23 of inner wall fixedly connected with of dead slot 25, be equipped with T-slot 7 on fixed plate 5, the inner wall sliding connection of T-slot 7 has second pinion rack 13, the upper end fixed connection fixed block 6 of fixed plate 5, it is connected with dwang 9 to rotate on the fixed block 6, fixedly connected with and 13 first gear 10 of meshing mutually of second pinion rack 13 and the second gear 8 of keeping away from second pinion rack 13 on the dwang 9, second gear 8 and 24 sliding connection of rectangular channel, second gear 8 can with first pinion rack 4 intermeshing, and drive first pinion rack 4 and remove.

The lower end of the second toothed plate 13 is fixedly connected with a long plate 14, a second limiting mechanism is arranged between the long plate 14 and the two magnetic blocks 23, the second limiting mechanism comprises an expansion link 15 fixed at the upper end of the long plate 14, a second spring 17 is sleeved on the expansion link 15, a T magnetic block 16 is fixedly connected to the upper ends of the second spring 17 and the expansion link 15 together, the upper part of the T magnetic block 16 has no magnetism, only the bottom is provided with the magnetic block, the T magnetic block 16 is matched with the empty slot 25, the magnetic poles of the T magnetic block 16 and the two magnetic blocks 23 are different, the fixed plate 5 and one end of the sleeve 12 are fixedly connected with the wall body 11 together, two buffer mechanisms are arranged between the wall body 11 and the fixed plate 5, each buffer mechanism comprises a first L-shaped plate 18 fixedly connected with the lower end of the fixed plate 5, the side wall body 11 is fixedly connected with a second L-shaped plate 19, and, the third spring 20 has a certain cushioning effect on the sensor body 1.

In the utility model, when the worker installs the sensor, the sensor body 1 is horizontally aligned with the fixed plate 5, then the sensor body 1 is pushed forward, the sensor body 1 drives the cylinder 3 to be pushed forward, when pushing, the limiting block 21 at the lower end of the cylinder 3 extrudes the sleeve 12 and slides into the limiting groove 2, the first toothed plate 4 at the upper end of the cylinder 3 rubs against the second gear 8 and drives the second gear 8 to rotate, the second gear 8 rotates to drive the rotating rod 9 and the first gear 10 to rotate, the first gear 10 rotates to drive the second toothed plate 13 to move upwards, the second toothed plate 13 moves upwards to drive the long plate 14 to move upwards, the long plate 14 drives the telescopic rod 15, the second spring 17 and the T magnetic block 16 to move upwards together, when pushing the cylinder 3 again, no teeth are arranged on the first toothed plate 4, the T magnetic block 16 cannot be driven to move upwards, when pushing the cylinder 3 to continue to move forwards, and the limiting block 21 is finally clamped in the hollow groove 25 to complete the installation of the sensor.

When the cylinder 3 is pushed again, the first toothed plate 4 and the second gear 8 at the upper end of the cylinder 3 rub against each other and drive the second gear 8 and the first gear 10 to rotate, the second toothed plate 13 is driven to move upwards, the second toothed plate 13 moves upwards to drive the long plate 14 to move upwards, the long plate 14 drives the telescopic rod 15, the second spring 17 and the T magnetic block 16 to move upwards together until the T magnetic block 16 and the two magnetic blocks 23 attract each other and block the empty groove 25, so that the limiting block 21 slides into the limiting groove 2, and when the cylinder 3 is pushed again, the telescopic rod 15 and the second spring 17 are compressed; then the cylinder 3 is pulled backwards, when the first toothed plate 4 on the cylinder 3 is rubbed with the second gear 8, the second gear 8 rotates to drive the first gear 10 to rotate, the second toothed plate 13 is driven to move downwards, the second toothed plate 13 moves downwards to drive the long plate 14 to move downwards, the long plate 14 drives the telescopic rod 15, the second spring 17 and the T magnet 16 to move downwards together, the telescopic rod 15 and the second spring 17 are not compressed and reset, but the T magnet 16 is still attracted with the two magnets 23, the sensor body 1 is continuously pulled, under the blockage of the T magnet 16, the limiting block 21 at the lower end of the cylinder 3 slides in the limiting groove 2 and with the T magnet 16, along with the pulling of the cylinder 3, the second toothed plate 13 and the long plate 14 are driven to move downwards, the long plate 14 drives the telescopic rod 15 and the second spring 17 to move downwards together, the second spring 17 pulls the T magnet 16, so that the T magnet 16 is separated from the two magnets 23, the T magnetic block 16 no longer blocks the empty slot 25, and the sensor body 1 is dismounted.

First L shaped plate 18 and sensor body 1 fixed connection, second L shaped plate 19 and wall body 11 fixed connection, under the influence of external environment, probably rock sensor body 1, influence the work at sensor body 1, and third spring 20, first L shaped plate 18, second L shaped plate 19 play certain cushioning effect under the combined action to sensor body 1.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides an intelligence building sensor mounting structure for temperature control system, includes sensor body (1) and fixed plate (5), its characterized in that, the one end lateral wall fixedly connected with cylinder (3) of sensor body (1), the upper end fixedly connected with first pinion rack (4) of cylinder (3), the lower extreme of cylinder (3) is equipped with first stop gear, the lateral wall fixedly connected with of fixed plate (5) and cylinder (3) assorted sleeve (12), the upper end of sleeve (12) runs through and is equipped with rectangular channel (24), the lower extreme of sleeve (12) is equipped with dead slot (25), the inner wall fixedly connected with two relative magnetic path (23) of dead slot (25), be equipped with T-slot (7) on fixed plate (5), the inner wall sliding connection of T-slot (7) has second pinion rack (13), the upper end fixed connection fixed block (6) of fixed plate (5), rotate on fixed block (6) and be connected with dwang (9), second gear (8) of first gear (10) and keeping away from second pinion rack (13) that fixedly connected with and second pinion rack (13) engaged with on dwang (9), second gear (8) and rectangular channel (24) sliding connection, the lower extreme fixedly connected with long board (14) of second pinion rack (13), be equipped with second stop gear between long board (14) and two magnetic path (23), the common and wall body (11) fixed connection of one end of fixed plate (5) and sleeve (12), be equipped with two buffer gear between wall body (11) and fixed plate (5).

2. The sensor mounting structure for the intelligent building temperature control system according to claim 1, wherein the first limiting mechanism comprises a limiting groove (2) on a cylinder (3), a first spring (22) is fixedly connected to the inner wall of the limiting groove (2), a limiting block (21) is fixedly connected to the other end of the first spring (22), and the limiting block (21) is slidably connected to the inner wall of the limiting groove (2).

3. The sensor mounting structure for the intelligent building temperature control system according to claim 2, wherein the second limiting mechanism comprises a telescopic rod (15) fixed to the upper end of the long plate (14), a second spring (17) is sleeved on the telescopic rod (15), and the upper ends of the second spring (17) and the telescopic rod (15) are fixedly connected with a T magnet (16) together.

4. The sensor mounting structure for the intelligent building temperature control system according to claim 3, wherein the buffer mechanism comprises a first L-shaped plate (18) fixedly connected with the lower end of the fixing plate (5), a second L-shaped plate (19) is fixedly connected with the side wall of the wall body (11), and two third springs (20) are fixedly connected between the first L-shaped plate (18) and the second L-shaped plate (19).

5. The sensor mounting structure for the intelligent building temperature control system according to claim 4, wherein the gear teeth on the first toothed plate (4) are indirectly distributed, and the first toothed plate (4) and the second gear (8) are meshed with each other.

6. The sensor mounting structure for the intelligent building temperature control system according to claim 5, wherein the T magnetic block (16) is matched with the empty slot (25), and the magnetic poles of the T magnetic block (16) and the two magnetic blocks (23) are different.

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