CN107355958B

CN107355958B - Detection device and air conditioner

Info

Publication number: CN107355958B
Application number: CN201710769000.1A
Authority: CN
Inventors: 叶海林; 刘志强; 毛先友
Original assignee: GD Midea Air Conditioning Equipment Co Ltd
Current assignee: GD Midea Air Conditioning Equipment Co Ltd
Priority date: 2017-08-30
Filing date: 2017-08-30
Publication date: 2023-04-25
Anticipated expiration: 2037-08-30
Also published as: CN107355958A

Abstract

The invention discloses a detection device and an air conditioner, wherein the detection device comprises: a front case having a mounting cavity with one side open, and a side wall adjacent to and/or opposite to the open side having light transmittance; the rear cover is detachably connected with the front shell corresponding to the opening side of the mounting cavity so as to seal the opening, so that a closed mounting cavity is formed; the infrared signal assembly is used for transmitting and/or receiving detection signals, and the infrared signal assembly is detachably arranged in the installation cavity.

Description

Detection device and air conditioner

Technical Field

The present invention relates to the field of air conditioning technologies, and in particular, to a detection apparatus and an air conditioner.

Background

Along with the improvement of the living standard of people, the intelligent requirements of people on the air conditioner are higher and higher. The air conditioner is intelligent, and the information acquisition is not needed, so that the requirement of the information acquisition device is higher and higher. The infrared detection device is an information acquisition device and comprises a transmitting head and a receiving head, and the phenomenon that the transmitting head directly transmits infrared rays to the receiving head frequently occurs because the receiving head receives the infrared rays and the transmitting head transmits the infrared rays, so that the result detected by the infrared detection device is inaccurate.

Disclosure of Invention

The invention mainly aims to provide a detection device, which aims to improve the working precision of the detection device.

In order to achieve the above object, the present invention provides a detection device, including:

a front case having a mounting cavity with one side open, and a side wall adjacent to and/or opposite to the open side having light transmittance;

the rear cover is detachably connected with the front shell corresponding to the opening side of the mounting cavity so as to seal the opening, so that a closed mounting cavity is formed;

the infrared signal assembly is used for transmitting and/or receiving detection signals, and the infrared signal assembly is detachably arranged in the mounting cavity.

Preferably, a buckling position is formed in the side wall of the mounting cavity, a fixing buckle is arranged on the rear cover corresponding to the buckling position, and the fixing buckle is buckled into the buckling position from the inside of the mounting cavity.

Preferably, a plurality of support ribs are arranged in the mounting cavity, and the supports are respectively arranged at two ends of the mounting cavity;

and a limiting buckle is arranged on the side wall of the mounting cavity, one side surface of the infrared signal assembly is abutted with the supporting rib, and the other opposite side surface is abutted with the limiting buckle.

Preferably, a pressing rib is arranged on one side of the rear cover facing the mounting cavity, and extends into the mounting cavity to be abutted with the side face, facing the limit buckle, of the infrared signal assembly.

Preferably, the pressing rib is arranged along the periphery of the rear cover, and an avoidance gap is formed on the pressing rib corresponding to the limit buckle; the rib presses against the side wall of the installation cavity.

Preferably, a sealant layer is provided between the rear cover and the front case.

Preferably, the infrared signal assembly comprises:

the circuit board is provided with a control circuit;

the infrared emission head and the receiving head are electrically connected with the control circuit;

the bracket is provided with a first mounting hole corresponding to the transmitting head and a second mounting hole corresponding to the receiving head, the first mounting hole and/or the second mounting hole are blind holes, and the opening of the blind holes is opposite to the circuit board;

the transmitting head is installed in the first installation hole, and the receiving head is installed in the second installation hole.

Preferably, a first pin hole is formed in the bottom of the first mounting hole, and a pin of the transmitting head penetrates through the first pin hole to be connected with the circuit board;

and a second pin hole is formed in the bottom of the second mounting hole, and a pin of the receiving head penetrates through the second pin hole to be connected with the circuit board.

Preferably, sealing ribs are arranged between the transmitting head and the pins of the transmitting head, the sealing ribs are arranged along the circumferential direction of the transmitting head, and the sealing ribs are tightly matched with the first mounting holes.

Preferably, the number of the first mounting holes and the emission heads is plural;

the first mounting holes are arranged along the length direction of the support, and the first mounting holes are arranged in a radial mode on the support so that the emission heads are arranged in a radial mode.

Preferably, the side walls of the mounting cavity facing the first mounting hole and the second mounting hole are light-transmitting decorative plates, and a first light-transmitting groove is formed in the position, corresponding to the first mounting hole, of each light-transmitting decorative plate; and/or the number of the groups of groups,

and a second light transmission groove is formed at a position corresponding to the second mounting hole.

Preferably, one end of the emitting head far away from the circuit board is abutted with the bottom of the first light-transmitting groove; and/or the number of the groups of groups,

one end of the receiving head, which is far away from the circuit board, is abutted with the bottom of the second light-transmitting groove.

Preferably, the side walls of the mounting cavity facing the first mounting hole and the second mounting hole are light-transmitting decorative plates;

the light-transmitting decorative plate is provided with a partition groove, and the partition groove is positioned between the second mounting hole and the adjacent first mounting hole and corresponds to the position of the light-transmitting decorative plate so as to block signals between the transmitting head and the receiving head from being transmitted in the light-transmitting decorative plate.

Preferably, the number of the partition grooves is a plurality, and the plurality of the partition grooves are respectively arranged on the inner side and the outer side of the light-transmitting decorative plate;

the sum of the groove depths of the separation grooves respectively arranged on the inner side and the outer side of the light-transmitting decorative plate is larger than or equal to the thickness of the light-transmitting decorative plate.

The invention further provides an air conditioner, which comprises a detection device, wherein the detection device comprises: a front case having a mounting cavity with one side open, and a side wall adjacent to and/or opposite to the open side having light transmittance;

Preferably, the air conditioner is a cross-flow cabinet air conditioner, the indoor unit of the cross-flow cabinet air conditioner comprises a shell, the shell is in a columnar arrangement, an air outlet of the indoor unit is arranged along the height direction of the shell, and the detection decoration is arranged in the air outlet.

According to the technical scheme, the rear cover is used for blocking the opening of the front shell, so that the mounting cavity is a sealed mounting cavity, light is prevented from entering the mounting cavity from a gap between the front shell and the rear cover, and therefore the influence of light or signals entering the mounting cavity from the opening side of the front shell on signal emission and signal receiving operation is avoided, the influence of external signals on signal emission is reduced, meanwhile, the interference of the external signals on signal receiving is also reduced, and the detection precision of the detection device is higher.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an embodiment of a cabinet air conditioner of the present invention;

FIG. 2 is a schematic structural diagram of an embodiment of the detecting device of the present invention;

FIG. 3 is a schematic structural diagram of another embodiment of the detecting device of the present invention;

FIG. 4 is a schematic structural view of a detecting device according to another embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view of the structure M-M in FIG. 4;

FIG. 6 is an enlarged view of a portion of FIG. 5 at A;

FIG. 7 is a partial enlarged view at B in FIG. 5;

FIG. 8 is a schematic view of the structure of the front and rear covers of the present invention;

fig. 9 is a schematic structural view of the bracket.

Reference numerals illustrate:

reference numerals	Name of the name	Reference numerals	Name of the name
				100	Shell body	110	Air outlet
500	Detection device	510	Front shell
				511	Isolation groove	512	Limiting buckle
520	Sealing gasket	521	Boss
				522	Spacing foot	523	Avoidance hole
530	Support frame	534	Spacing protruding muscle
				535	Hemming edge	536	Mounting groove
540	Circuit board	550	Transmitting head
				551	Sealing rib	560	Receiving head
570	Rear cover	571	Press bar
				572	Avoidance gap	531	First mounting hole
532	Second mounting hole	533	Fixing hole
				573	Fixing buckle	513	Buckling position
514	Supporting rib	537	First pin hole

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

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

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present invention are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

The specific structure of the detection device will be mainly described below. It should be noted that, in order to avoid repeating the description of the same feature multiple times, the features in the following embodiments may be applied to and organically combined with other embodiments, and it should be understood that the description has provided an embodiment in which the feature is applied to other embodiments.

Referring to fig. 1 to 9, in an embodiment of the present invention, the detecting apparatus 500 includes:

a front case 510, the front case 510 having a mounting cavity with one side opened, and a side wall adjacent to and/or opposite to the opened side having light transmittance;

a rear cover 570 detachably connected to the front case 510 at an opening side of the rear cover 570 corresponding to the installation cavity to block the opening to form a closed installation cavity;

In particular, in the present embodiment, there may be many forms of the front case 510 and the rear cover 570, wherein the front case 510 is exemplified as the arc-shaped case 100, and the rear cover 570 is exemplified as the plate-shaped case. Through the cooperation of the front shell 510 and the rear cover 570, a sealed mounting cavity is formed, so that moisture, light and air flow in the external environment cannot influence the work of the transmitting head 550 and the receiving head 560, thereby being beneficial to improving the working stability of the transmitting head 550 and the receiving head 560, and further effectively improving the detection precision. There are many ways to connect the front case 510 and the rear cover 570, such as by screw connection, snap connection, and the like.

The infrared signal assembly is installed in the installation cavity in a plurality of modes, such as screw connection, buckle connection or adhesive connection and the like. The infrared signal assembly includes a transmitting head 550 for transmitting signals and/or a receiving head 560 for receiving signals.

The rear cover 570 may close the opening in a variety of ways to make the mounting cavity airtight, for example, the rear cover 570 itself may be sealingly connected to the inner sidewall of the mounting cavity, or after the rear cover 570 is connected to the front case 510, the gap between the rear cover 570 and the inner sidewall of the mounting cavity may be sealed by a sealing material or component (such as a gasket 520, a sealing ring, a sealant, etc.).

In this embodiment, the rear cover 570 seals the opening of the front shell 510, so that the mounting cavity is a sealed mounting cavity, and light is blocked from entering the mounting cavity from the gap between the front shell 510 and the rear cover 570, so that the influence of light or signals entering the mounting cavity from the opening side of the front shell 510 on signal transmission and signal receiving operation is avoided, the influence of external signals on signal transmission is reduced, and meanwhile, the interference of external signals on signal receiving is also reduced, so that the detection precision of the detection device 500 is higher.

In order to increase the connection strength and stability between the rear cover 570 and the front case 510, a fastening portion 513 is formed on a side wall of the mounting cavity, a fixing fastener 573 is disposed on the rear cover 570 corresponding to the fastening portion 513, and the fixing fastener 573 is fastened into the fastening portion 513 from the mounting cavity. In this embodiment, the fastening portions 513 are arranged along the circumferential direction of the inner sidewall of the installation cavity, and the number of the fastening portions can be set according to actual requirements, for example, four fastening portions. The four fastening locations 513 are respectively arranged on two opposite side walls of the installation cavity. The fixing buckle 573 is disposed on one side of the rear cover 570 facing the mounting cavity, the fixing buckle 573 is an elastic buckle, and one end of the elastic buckle away from the cover plate extends outwards. When the fixing buckle 573 is buckled into the buckling position 513, elastic deformation needs to occur to enter the buckling position 513, after the fixing buckle 573 is buckled into the buckling position 513, the fixing buckle 573 still generates elastic deformation as an example, and at this time, the fixing buckle 573 has tension on the buckling position 513, so that the installation of the rear cover 570 and the front shell 510 is more stable.

In order to increase the connection strength and stability between the rear cover 570 and the front case 510, a plurality of supporting ribs 514 are arranged in the mounting cavity, and the supports are respectively arranged at two ends of the mounting cavity; a limit button 512 is disposed on a side wall of the mounting cavity, one side surface of the infrared signal assembly is abutted to the supporting rib 514, and the opposite other side surface is abutted to the limit button 512. In this embodiment, the infrared signal assembly includes a circuit board 540, one side of the circuit board 540 is abutted against the supporting rib 514, and supported by the supporting rib 514, and the other side is abutted against the limiting buckle 512, so as to be limited by the limiting buckle 512. I.e., the circuit board 540 is clamped between the support rib 514 and the limit button 512. By simultaneously arranging the supporting ribs 514 and the limit buckles 512, the installation of the infrared signal assembly is very stable and reliable. The limit button 512 is the same as the limit button 512 in the previous embodiment, that is, the limit button 512 is buckled with the limit button 512 of the rear cover 570, and is used for limiting the infrared signal assembly, so that the effect of the limit button is fully utilized, the space in the installation cavity is reasonably utilized, and the structure of the detection device 500 is very compact.

In order to further fix the infrared signal assembly, a pressing rib 571 is disposed on a side of the rear cover 570 facing the mounting cavity, and the pressing rib 571 extends into the mounting cavity to abut against a side of the infrared signal assembly facing the limit button 512. The ribs 571 are arranged in a strip shape, the ribs 571 are arranged along the side edge of the cover plate, and the ribs 571 can be arranged in a plurality of shapes, for example, in a ring shape, so that the circuit board 540 in the infrared signal assembly is pressed around the ribs 571. The ribs 571 may be arranged in sections or integrally. Through the setting of press bar 571 for the position of infrared signal subassembly is very stable, thereby can not take place the position deviation in its course of working, thereby avoid appearing receiving the signal, perhaps the phenomenon that signal transmission can not go out, be favorable to improving detection device 500's detection stability.

In order to better fix the infrared signal assembly, the pressing rib 571 is disposed along the periphery of the rear cover 570, and the pressing rib 571 is provided with a avoiding gap 572 corresponding to the limit button 512; the pressing ribs 571 are attached to the side wall of the installation cavity. Further stabilizes the position of the infrared signal assembly, further improving the detection stability of the detection device 500.

To further prevent interference signals or light from entering the mounting cavity from the rear cover 570, a sealant layer is provided between the rear cover 570 and the front case 510. By the arrangement of the sealant layer, the sealability between the rear cover 570 and the front case 510 is higher, and at the same time, the connection stability between the rear cover 570 and the front case 510 is also increased.

The structure of an infrared signal assembly is specifically described below, the infrared signal assembly comprising:

a circuit board 540, wherein the circuit board 540 is provided with a control circuit;

an infrared emission head 550 and a receiving head 560, the emission head 550 and the receiving head 560 being electrically connected to the control circuit;

the bracket 530 is provided with a first mounting hole 531 corresponding to the emitter head 550, and a second mounting hole 532 corresponding to the receiver head 560, wherein the first mounting hole 531 and/or the second mounting hole 532 are blind holes, and the opening of the blind holes is opposite to the circuit board 540;

the emitting head 550 is mounted in the first mounting hole 531, and the receiving head 560 is mounted in the second mounting hole 532.

Specifically, in the present embodiment, the circuit board 540 has a control circuit thereon, and the shape of the circuit board 540 may be various, for example, square, rectangular, circular, elliptical, etc., and is not particularly limited herein. The shape of the infrared emission head 550 and the receiving head 560 is not particularly limited, and the infrared emission head 550 is exemplified by a long cylindrical shape, and the receiving head 560 is exemplified by a rectangular parallelepiped shape. The shape of the support 530 may be varied, such as elongated, circular, square, oval, etc. The first and second mounting

holes

531 and 532 are arranged along a length square of the bracket 530, and the first and second mounting

holes

531 and 532 are opened along a height direction of the bracket 530. The shape of the first mounting hole 531 is adapted to the infrared emission head 550 so that the infrared emission head 550 can be mounted in the first mounting hole 531. The shape of the second mounting hole 532 is adapted to the shape of the receiving head 560 so that the infrared receiving head 560 can be mounted in the second mounting hole 532.

The number of the infrared emitting heads 550 may be many, and all the infrared emitting heads 550 may be arranged along the length of the circuit board 540, or the number of the infrared receiving heads 560 may be many, in this embodiment, one infrared emitting head is taken as an example. There may be many positional relationships between the infrared receiving heads 560 and the plurality of infrared emitting heads 550, for example, the infrared emitting heads 550 may be arranged randomly among the infrared emitting heads 550, taking the number of the infrared emitting heads 550 on both sides of the infrared receiving heads 560 as an example. Of course, the number of the first mounting holes 531 on the bracket 530 is comparable to the number of the infrared emission heads 550, so that each of the infrared emission heads 550 can be mounted into the first mounting hole 531. Similarly, the number of second mounting holes 532 on the bracket 530 is comparable to the number of infrared receiving heads 560, such that each infrared receiving head 560 can be mounted into a second mounting hole 532.

Since the first mounting hole 531 and the second mounting hole 532 are blind holes, light and signals cannot pass through the bottom of the blind holes and enter the first mounting hole 531 and the second mounting hole 532, so that the transmitting head 550 and the receiving head 560 cannot be interfered by signals from the bottom of the blind holes, and external signals are effectively prevented from interfering with signal transmission of the transmitting head 550 and signal reception of the receiving head 560.

In this embodiment, by installing the infrared emission head 550 in the first installation hole 531, installing the infrared receiving head 560 in the second installation hole 532, and setting the first installation hole 531 and the second installation hole 532 as blind holes, external signals cannot enter from the bottom of the blind holes, so that signal interference of external information on the infrared emission head 550 and the receiving head 560 is greatly blocked, and the operation of the emission head 550 and the receiving head 560 is more stable and accurate; meanwhile, by the arrangement of the first mounting holes 531 and the second mounting holes 532, signals between the infrared emission head 550 and the infrared receiving head 560 cannot be directly transmitted, but can be transmitted only by reflection of an external object, so that the phenomenon of signal mistransmission is avoided, the phenomenon of misoperation is avoided, and the detection accuracy of the infrared detection device 500 is improved; meanwhile, as the infrared emission head 550 and the receiving head 560 are arranged in the blind holes, the installation of the emission head 550 and the receiving head 560 is more stable and reliable than the installation of the emission head 550 and the receiving head 560 on the circuit board 540, which is beneficial to improving the installation stability of the emission head 550 and the receiving head 560 and facilitating the stable work thereof; particularly, the transmitting head 550 and the receiving head 560 are arranged in the blind holes, so that the transmitting head 550 and the receiving head 560 are closer to the light-transmitting decorative plate, the distance between the transmitting head 550 and the measured object is shortened, and the infrared light is attenuated less in the transmission process, so that the transmitting head 550 is beneficial to transmitting infrared light; similarly, the distance between the infrared receiving head 560 and the measured object is shortened, and the attenuation of the infrared light reflected back is reduced.

In order to improve the mounting of the pins of the transmitting head 550 and the receiving head 560, a first pin 537 hole is formed at the bottom of the first mounting hole 531, and the pin of the transmitting head 550 is connected with the circuit board 540 through the first pin 537 hole; a second pin hole is formed at the bottom of the second mounting hole 532, and a pin of the receiving head 560 passes through the second pin hole to be connected with the circuit board 540. In this embodiment, the hole diameter of the hole of the first pin 537 is equal to the diameter of the pin of the emitter head 550, and the pin of the emitter head 550 passes through the hole of the first pin 537 to be connected with the circuit board 540; the second pin hole has a diameter corresponding to the diameter of the pin of the receiving head 560, and the pin of the receiving head 560 is connected to the circuit board 540 through the second pin hole. Through the arrangement of the first pin 537 hole and the second pin hole, the pins of the transmitting head 550 and the receiving head 560 can directly penetrate through the first pin 537 hole and the second pin hole to be connected with the circuit board 540, so that the transmitting head 550 and the receiving head are very convenient to install, and the infrared detection device 500 is very compact in structure.

For example, the accuracy of infrared detection is improved, interference of external light is avoided, sealing ribs 551 are arranged between the emitting head 550 and pins thereof, the sealing ribs 551 are arranged along the circumferential direction of the emitting head 550, and the sealing ribs 551 are tightly matched with the first mounting holes 531. The sealing rib 551 is arranged at one end of the infrared emission head 550 close to the pin, and the sealing rib 551 is arranged around the end of the infrared emission head 550. When the infrared emission head 550 is installed in the first installation hole 531, the outer side wall of the sealing rib 551 is attached to the inner wall of the first installation hole 531, so that light is prevented from entering the first installation hole 531 from a gap between the infrared emission head 550 and the first installation hole 531, and the accuracy of the emission of the infrared emission head 550 is improved.

In order to improve the efficiency and the accuracy of the infrared detection, the number of the first mounting holes 531 and the emission heads 550 are multiple; the first mounting holes 531 are arranged along the length direction of the support 530, and the first mounting holes 531 are arranged radially on the support 530, so that the emission heads 550 are arranged radially.

The radial arrangement of the first mounting holes 531 means that the plurality of first mounting holes 531 are arranged on the same circular arc such that the hole depth directions of the adjacent first mounting holes 531 are different. When the emitting heads 550 are arranged radially, the detecting signals emitted by the plurality of emitting heads 550 are cambered surfaces, so as to greatly increase the detecting range. In some embodiments, in order to better implement the radial arrangement of the first mounting holes 531, the support 530 is disposed in an arc shape, and a plurality of the first mounting holes 531 are arranged along the extending direction of the support 530.

In order to further improve the detection precision, the side walls of the mounting cavities facing the first mounting holes 531 and the second mounting holes 532 are light-transmitting decorative plates, and a first light-transmitting groove is formed in the position of the light-transmitting decorative plates corresponding to the first mounting holes 531; and/or a second light-transmitting groove is formed at a position corresponding to the second mounting hole 532. The color of the light-transmitting decorative board may be set according to more practical requirements, for example, when the detecting device 500 is an infrared detecting device 500, the color of the light-transmitting decorative board may be dark red. Through the setting of printing opacity groove for boss 521 on the sealed pad 520 can install in the printing opacity groove, makes sealed pad 520 shelter from the cell wall in printing opacity groove, thereby, avoid the signal to transmit along the printing opacity decorative board, and lead to receiving head 560 to receive by mistake. Therefore, signal interference is effectively reduced, and the infrared detection accuracy is improved.

To improve the detection precision, an end of the emitter 550 away from the circuit board 540 is abutted with the bottom of the first light-transmitting groove; and/or, an end of the receiving head 560 away from the circuit board 540 is abutted with a bottom of the second light-transmitting groove. In this embodiment, the transmitting head 550 and the receiving head 560 are disposed in the blind hole, so that the transmitting head 550 and the receiving head 560 are closer to the light-transmitting decorative board, the distance between the transmitting head 550 and the measured object is shortened, and the infrared light is attenuated less in the transmission process, so that the transmitting head 550 is facilitated to transmit the infrared light; similarly, the distance between the infrared receiving head 560 and the measured object is shortened, and the attenuation of the infrared light reflected back is reduced. In some embodiments, in order to better improve the infrared emission effect, the infrared emission head 550 is abutted to the bottom of the first light-transmitting groove, so that the stroke of the infrared light is further shortened; similarly, the infrared receiving head 560 is abutted against the bottom of the second light-transmitting groove, so that the distance between the measured object and the receiving head 560 is shortened, and the attenuation of signals is reduced.

In order to further improve the detection accuracy, the side walls of the mounting cavities facing the first mounting holes 531 and the second mounting holes 532 are light-transmitting decorative boards; the light-transmitting decorative plate is provided with a separation groove 511, and the separation groove 511 is located between the second mounting hole 532 and the adjacent first mounting hole 531 and corresponds to the light-transmitting decorative plate, so as to prevent signals between the transmitting head 550 and the receiving head 560 from being transmitted in the light-transmitting decorative plate. The partition groove 511 is provided on an inner side wall and/or an outer side wall of the light-transmitting decorative plate, and the partition groove 511 extends in a width direction of the light-transmitting decorative plate. By the arrangement of the isolation groove 511, signals cannot be transmitted from the area corresponding to the transmitting head 550 to the area corresponding to the receiving head 560, so that signal transmission in the light-transmitting decorative board is blocked. Thus, the signal is prevented from being transmitted along the light-transmitting decorative plate, and the receiving head 560 is prevented from receiving by mistake. And further effectively reduces signal interference and is beneficial to improving the accuracy of infrared detection.

In some embodiments, in order to further improve the blocking effect, the number of the blocking grooves 511 is plural, and the blocking grooves 511 are respectively disposed at the inner side and the outer side of the light-transmitting decorative plate; the sum of the groove depths of the partition grooves 511 provided at the inner and outer sides of the light-transmitting decorative plate, respectively, is greater than or equal to the thickness of the light-transmitting decorative plate. Through setting up the separation groove 511 in inboard and outside simultaneously to the sum of the groove depth of the separation groove 511 in inboard and outside is greater than the thickness of printing opacity decorative board, makes the signal of transmission in the printing opacity decorative board, must be cut off, thereby effectually ensured that the signal can not pass in infrared decorative board, is favorable to further improving the separation effect, in order to improve detection precision.

In order to further improve the detection accuracy, the detection device 500 further includes a sealing pad 520, and the sealing pad 520 is provided with an avoidance hole 523 corresponding to the first mounting hole 531 and the second mounting hole 532; the gasket 520 is disposed at a side of the bracket 530 facing away from the circuit board 540 to seal the peripheral edges of the first and second mounting

holes

531 and 532, and the gasket 520 is detachably connected to the bracket 530. The sealing gasket 520 is in a sheet-shaped arrangement, and the sealing gasket 520 is attached to the support 530, so that light cannot enter from the first mounting hole 531 and the second mounting hole 532 away from the hole opening of the circuit board 540, and thus the light is prevented from affecting the operation of the transmitting head 550 and the receiving head 560 from the front, and the accuracy of signal transmission and reception is effectively improved.

In some embodiments, in order to improve the mounting stability of the gasket 520, a limit flange 535 is disposed on the periphery of the side of the support 530 facing away from the circuit board 540, where the limit flange 535 encloses to form a mounting groove 536, and the gasket 520 is tightly matched with the mounting groove 536. The limit flange 535 is formed in an annular shape, and the openings of the first mounting hole 531 and the second mounting hole 532 are formed in the region thereof by the arrangement of the limit flange 535. When the gasket 520 is mounted on the bracket 530, the limit flaps 535 define the position of the gasket 520, thereby increasing the stability of the gasket 520.

In order to further improve stability of the sealing gasket 520, a limiting leg 522 is disposed on a side of the sealing gasket 520 facing the support 530, and a fixing hole 533 is formed on the support 530 corresponding to the limiting leg 522; the limiting leg 522 is tightly fitted to the fixing hole 533. The shape of the limiting legs 522 may be varied, for example, a columnar configuration. The number of the limiting legs 522 may be plural, for example, two limiting legs 522 are respectively inserted into the fixing holes 533 of the support 530, so that the gasket 520 is very stably mounted on the support 530.

In order to improve the detection precision, a side of the first mounting hole 531 opposite to the circuit board 540 is provided with a limiting rib 534 along the periphery of the first mounting hole 531, and the avoidance hole 523 is sleeved on the limiting rib 534. Through the setting of protruding muscle, protruding muscle separates the sealing strip outside first mounting hole 531 and second mounting hole 532, avoids having elastic sealed pad 520 to cover up the drill way of first mounting hole 531 and second mounting hole 532 to make emitter 550 can effectually go out the signal reflection, simultaneously, also guarantee that receiver 560 can receive the signal in a larger scale, thereby be favorable to improving the precision. In addition, through the arrangement of the convex ribs, the avoiding holes 523 are sleeved on the convex ribs, so that the sealing gasket 520 is limited, namely, the stability of the sealing gasket 520 in the detection device 500 is improved.

In order to further improve the detection accuracy of the detection device 500, a boss 521 is disposed on the sealing pad 520 opposite to the support 530, and the boss 521 is disposed corresponding to the avoidance hole 523, so that the hole depth of the avoidance hole 523 is greater than the thickness of the sealing pad 520. Through the arrangement of the boss 521, the thickness of the sealing gasket 520 at the boss 521 is larger than the thickness of other positions of the sealing gasket 520, so that the sealing gasket 520 corresponding to the avoiding hole 523 can block the influence of light rays in a large range (along the hole depth direction). At the same time, the signal of the transmitting head 550 is prevented from being transmitted to the corresponding escape hole 523 of the receiving head 560 through the surface of the sealing pad 520 and then entering the receiving head 560. Thereby greatly reducing the possibility of erroneous reception of signals and improving the detection accuracy of the detection device 500.

The invention also provides an air conditioner, which comprises a shell 100 and a detection device 500, wherein the specific structure of the detection device 500 refers to the above embodiment, and because the air conditioner adopts all the technical schemes of all the embodiments, the air conditioner at least has all the beneficial effects brought by the technical schemes of the embodiments, and the description is omitted herein. The casing 100 is specifically an air outlet 110, and the infrared detection device 500 is disposed in the middle of the air outlet 110.

The air conditioner is a cross-flow cabinet air conditioner, the indoor unit of the cross-flow cabinet air conditioner comprises a shell 100, the shell 100 is in a columnar arrangement, an air outlet 110 of the indoor unit is arranged along the height direction of the shell 100, and the detection decoration is arranged in the air outlet 110. The indoor unit of the air conditioner comprises an upper air guide assembly and a lower air guide assembly, and the upper air guide assembly and the lower air guide assembly are arranged corresponding to the air outlet 110; the infrared detection decoration is arranged between the upper air guide assembly and the lower air guide assembly. The upper wind guide component is an upper wind guide component without wind sense, and/or the lower wind guide component is a lower wind guide component without wind sense.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the description of the present invention and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the invention.

Claims

1. A detection apparatus, characterized by comprising:

the infrared signal assembly is used for transmitting and/or receiving detection signals and is detachably arranged in the mounting cavity;

a buckling position is formed on the side wall of the mounting cavity, a fixing buckle is arranged on the rear cover corresponding to the buckling position, and the fixing buckle is buckled into the buckling position from the inside of the mounting cavity;

a plurality of supporting ribs are arranged in the mounting cavity, and the supports are respectively arranged at two ends of the mounting cavity;

a limiting buckle is arranged on the side wall of the mounting cavity, one side surface of the infrared signal assembly is abutted with the supporting rib, and the other opposite side surface is abutted with the limiting buckle;

a pressing rib is arranged on one side of the rear cover facing the mounting cavity, and extends into the mounting cavity to be abutted with the side surface of the infrared signal assembly facing the limit buckle;

the pressing rib is arranged along the periphery of the rear cover, and an avoidance gap is formed on the pressing rib corresponding to the limit buckle; the rib presses against the side wall of the installation cavity.

2. The test device of claim 1, wherein a sealant layer is disposed between the rear cover and the front housing.

3. The detecting device according to claim 1 or 2, wherein,

the infrared signal assembly includes:

the circuit board is provided with a control circuit;

4. The detecting device according to claim 3, wherein a first pin hole is formed at the bottom of the first mounting hole, and a pin of the emitter head passes through the first pin hole to be connected with the circuit board;

5. A test device according to claim 3, wherein sealing ribs are provided between the emitter head and the pins thereof, the sealing ribs being arranged circumferentially of the emitter head, the sealing ribs being in close fit with the first mounting holes.

6. The detecting device according to claim 3, wherein the number of the first mounting holes and the emitting heads is plural;

7. The detecting device according to claim 3, wherein the side walls of the mounting cavity facing the first mounting hole and the second mounting hole are light-transmitting decorative plates, and a first light-transmitting groove is formed in the position of the light-transmitting decorative plates corresponding to the first mounting hole; and/or a second light transmission groove is formed at the position corresponding to the second mounting hole.

8. The detecting device for detecting the rotation of a motor rotor as claimed in claim 7, wherein an end of said emitter head which is away from said circuit board is abutted against a bottom of said first light-transmitting groove; and/or one end of the receiving head far away from the circuit board is abutted with the bottom of the second light-transmitting groove.

9. The detecting device according to claim 3, wherein a side wall of the mounting chamber facing the first mounting hole and the second mounting hole is a light-transmitting decorative plate; the light-transmitting decorative plate is provided with a partition groove, and the partition groove is positioned between the second mounting hole and the adjacent first mounting hole and corresponds to the position of the light-transmitting decorative plate so as to block signals between the transmitting head and the receiving head from being transmitted in the light-transmitting decorative plate.

10. The detecting device according to claim 9, wherein the number of the partition grooves is plural, and the plural partition grooves are provided on the inner side and the outer side of the light-transmitting decorative plate, respectively; the sum of the groove depths of the separation grooves respectively arranged on the inner side and the outer side of the light-transmitting decorative plate is larger than or equal to the thickness of the light-transmitting decorative plate.

11. An air conditioner comprising the detection device according to any one of claims 1 to 10.

12. The air conditioner of claim 11, wherein the air conditioner is a cabinet air conditioner, the indoor unit of the cabinet air conditioner comprises a shell, the shell is in a column shape, the air outlet of the indoor unit is arranged along the height direction of the shell, and the detection decoration is arranged in the air outlet.