CN113606692B - Engineering design device for laying area of radiation air conditioner - Google Patents

Abstract

The invention discloses an engineering design device for the laying area of a radiation air conditioner, which comprises a detector main body, wherein a probe is arranged on the detector main body, a protective shell is arranged on the outer side of the probe, a sealing piece is arranged in the protective shell, the protective shell is sealed when the detector is not used, a drying piece is arranged in the detector main body, water vapor attached to the probe is removed before the detector is used to prevent the water vapor from influencing the detection result, and a cleaning piece is arranged in the sealing piece, so that the engineering design method and the device for the laying area of the radiation air conditioner are different from the prior art, can be sealed when the detector is not used by arranging the sealing piece, avoid the long-time placement of the detector to cause the attachment of external dust and water vapor on the probe to influence the detection result, and treat the water vapor on the probe before the detector is used by arranging the cleaning piece and the drying piece, dust on the outside of the probe is disposed of when the rear closing plate is raised after use.

Description

Engineering design device for laying area of radiation air conditioner

Technical Field

The invention relates to the technical field of radiation air conditioners, in particular to an engineering design device for laying area of a radiation air conditioner.

Background

The energy consumption of the heating and ventilation air-conditioning system can account for more than half of the total energy consumption of a building, the energy problem needs to be solved urgently, the novel combined type radiation air-conditioning system is produced at the right moment, the combined type radiation air-conditioning system runs stably, a good indoor temperature and humidity environment can be maintained, strong 'blowing feeling' brought by a traditional air conditioner is effectively avoided, and the indoor air quality is improved.

Before the installation radiation air conditioner staff need be at indoor measurement multiple data, and with this lay the area of designing the air conditioner radiation board, need detect the humidity in the room at the measuring in-process, need use moisture detector at this in-process, but current moisture detector's probe all exposes in the external world, under the condition of placing for a long time, accumulate on the probe easily on dust and the steam in the air also can depend on the probe, influence the testing result, and then influence the installation of radiation board, cause the influence to design work. Therefore, an engineering design device for the laying area of the radiation air conditioner is provided.

Disclosure of Invention

The invention aims to provide an engineering design device for a laying area of a radiation air conditioner, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a radiation air conditioner lays area's engineering design device, includes the detector main part, and is preferred, be provided with the probe in the detector main part, the probe outside is provided with protecting crust, its characterized in that: the detector is characterized in that a sealing part is arranged in the protective shell, the protective shell is sealed when the detector is not used, a drying part is arranged in the detector main body, water vapor attached to the probe is removed before the detector is used, so that a detection result is prevented from being influenced, a cleaning part is arranged in the sealing part, and the water vapor and dust on the probe are cleaned when the detector is used and the sealing part is reset.

Preferably, the closing piece comprises a closing sleeve movably arranged in the protective shell, a closing plate is arranged at the top end of the closing sleeve, a mounting plate is arranged in the detector main body, a driving motor is arranged on the mounting plate, a screw rod is arranged at the output end of the driving motor, the closing sleeve is in threaded connection with the screw rod, and the closing sleeve is driven to move in the protective shell when the screw rod rotates.

Preferably, the drying part comprises a ventilation ring arranged in the detector main body, a connecting pipe is arranged on one side of the ventilation ring, fan blades are arranged in the connecting pipe, a supporting plate is arranged in the detector main body, a driving motor is arranged on the supporting plate, and the output end of the driving motor is in transmission connection with the fan blades;

the probe is characterized in that a ventilation pipe is connected to the top of the ventilation ring, a ventilation groove is formed in the sealing sleeve, the ventilation pipe is movably inserted into the ventilation groove, an air channel communicated with the ventilation groove is formed in the sealing plate, an electric heating wire is arranged in the ventilation ring, and air flow generated by rotation of the fan blades is heated by the electric heating wire and blown to the surface of the probe through the ventilation pipe, the ventilation groove and the air channel.

Preferably, the air duct is tapered from the outside of the closing plate to the center.

Preferably, a movable groove is formed in the closing plate, the cleaning piece comprises a movable plate movably arranged in the movable groove, a sliding groove is formed in the movable plate, an ejector rod is movably arranged in the sliding groove, guide rods are arranged on two sides of the ejector rod, the guide rods are movably arranged in the movable plate, an elastic piece is arranged on the outer side of each guide rod, a guide groove is formed in the protecting shell, when the closing plate ascends, the ejector rod drives the end portion of the movable plate to compress the probe through matching with the guide grooves, and then the outer side of the probe is cleaned in the ascending process.

Preferably, the elastic member is a spring, but not limited thereto.

Preferably, the guide way erects the groove including seting up at the first perpendicular groove and the second of protecting crust inner wall, the chute has all been seted up at first perpendicular groove and second perpendicular groove both ends when the closing plate descends, the activity of ejector pin tip is in first perpendicular inslot when the closing plate ascends, the ejector pin activity is in the second perpendicular inslot, the degree of depth that the groove was erected to the second is less than the degree of depth of first perpendicular groove.

Compared with the prior art, the invention has the beneficial effects that:

the invention is different from the prior art, the detector can be sealed when not in use by arranging the sealing piece, the influence of external dust and water vapor attached to the probe to the detection result caused by long-time placement is avoided, the water vapor on the probe is treated before use by arranging the cleaning piece and the drying piece, and the dust outside the probe is treated when the sealing plate is lifted after use.

Drawings

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

FIG. 2 is a partial cross-sectional structural schematic of the present invention;

FIG. 3 is a partial schematic view of FIG. 2 according to the present invention;

FIG. 4 is a schematic cross-sectional view of a closure sleeve according to the present invention;

FIG. 5 is a schematic cross-sectional view of the closure plate of the present invention;

FIG. 6 is a schematic cross-sectional view of FIG. 5 in accordance with the present invention;

FIG. 7 is a schematic cross-sectional view of the protective shell of the present invention.

In the figure: 1-a detector body; 2-a probe; 3-a protective shell; 4-a closure; 41-a closing sleeve; 42-a closing plate; 43-a mounting plate; 44-a drive motor; 45-lead screw; 5-drying the workpiece; 51-a vent ring; 52-connecting pipe; 53-fan blades; 54-a support plate; 55-a drive motor; 56-ventilation pipe; 57-ventilation slots; 58-air duct; 59-electric heating wire; 6-cleaning member; 61-a movable groove; 62-a movable plate; 63-a chute; 64-ejector pin; 65-a guide bar; 66-a resilient member; 7-a guide groove; 71-a first vertical slot; 72-a second vertical slot; 73-chute.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution:

an engineering design device for a radiation air conditioner laying area comprises a detector main body 1, wherein a probe 2 is arranged on the detector main body 1, a protective shell 3 is arranged on the outer side of the probe 2, a sealing part 4 is arranged in the protective shell 3, the protective shell 3 is sealed when a detector is not used, the sealing part 4 comprises a sealing sleeve 41 movably arranged in the protective shell 3, a sealing plate 42 is arranged at the top end of the sealing sleeve 41, a mounting plate 43 is arranged in the detector main body 1, a driving motor 44 is arranged on the mounting plate 43, a lead screw 45 is arranged at the output end of the driving motor 44, the sealing sleeve 41 is in threaded connection with the lead screw 45, and the sealing sleeve 41 is driven to move in the protective shell 3 when the lead screw 45 rotates;

the detector is characterized in that a drying part 5 is arranged in the detector main body 1, water vapor attached to the probe 2 is removed before the detector is used, so that a detection result is prevented from being influenced, the drying part 5 comprises a ventilation ring 51 arranged in the detector main body 1, a connecting pipe 52 is arranged on one side of the ventilation ring 51, fan blades 53 are arranged in the connecting pipe 52, a supporting plate 54 is arranged in the detector main body 1, a driving motor 55 is arranged on the supporting plate 54, and the output end of the driving motor 55 is in transmission connection with the fan blades 53;

the top of the ventilation ring 51 is connected with a ventilation pipe 56, a ventilation groove 57 is formed in the sealing sleeve 41, the ventilation pipe 56 is movably inserted in the ventilation groove 57, an air duct 58 communicated with the ventilation groove 57 is formed in the sealing plate 42, an electric heating wire 59 is arranged in the ventilation ring 51, and air flow generated by rotation of the fan blade 53 is heated by the electric heating wire 59 and blown to the surface of the probe 2 through the ventilation pipe 56, the ventilation groove 57 and the air duct 58;

the air duct 58 is gradually narrowed from the outer side of the closing plate 42 to the center, so that the speed of air flow in the air duct 58 is increased, and the drying effect is better

Be provided with cleaning member 6 in the closing member 4, end at the detector use steam and dust on the probe 2 are cleared up when closing member 4 resets, movable slot 61 has been seted up in the closing plate 42, cleaning member 6 sets up the fly leaf 62 in movable slot 61 including the activity, spout 63 has been seted up on the fly leaf 62, the activity is provided with ejector pin 64 in the spout 63, ejector pin 64 both sides are provided with guide bar 65, guide bar 65 activity sets up in fly leaf 62, the guide bar 65 outside is provided with elastic component 66, guide way 7 has been seted up on the protecting crust 3 when closing plate 42 ascends, ejector pin 64 drives fly leaf 62 tip through the cooperation with guide way 7 and compresses tightly probe 2, and then cleans the probe 2 outside at its in-process that rises.

The elastic member 66 is a spring.

Guide way 7 is including offering at the first vertical groove 71 and the second vertical groove 72 of protecting shell 3 inner wall, chute 73 has all been seted up at first vertical groove 71 and second vertical groove 72 both ends when closing plate 42 descends, ejector pin 64 tip activity is in first vertical groove 71 when closing plate 42 rises, ejector pin 64 activity is in second vertical groove 72, the degree of depth of second vertical groove 72 is less than the degree of depth of first vertical groove 71.

When the humidity sensor is used, the switch is turned on, the driving motor 44 is started to drive the screw rod 45 to rotate, the screw rod 45 drives the sealing sleeve 41 and the sealing plate 42 to move, the driving motor 55 is started simultaneously, the heating wire 59 is also electrified, air flow generated by the fan blades 53 is heated in the ventilation ring 51, enters the air channel 58 through the ventilation pipe 56 and the ventilation groove 57, and finally is blown to the surface of the probe 2. The probe 2 is dried in all directions along with the descending of the closing plate 42, at the moment, the ejector rod 64 moves in the first vertical groove 71, then the device can be used normally, after the use is finished, a switch is pressed down, the driving motor 44 is started to drive the closing plate 42 and the closing sleeve 41 to reset, at the moment, the ejector rod 64 moves from the first vertical groove 71 to the second vertical groove 72 through the inclined groove 73, when the closing plate 42 ascends, because the depth of the second vertical groove 72 is smaller than that of the first vertical groove 71, the ejector rod 64 can prop against the movable plate 62 in the second vertical groove 72 to enable the end part of the ejector rod to cling to the surface of the probe 2, and dust on the probe 2 is cleaned along with the ascending of the closing plate 42.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a radiation air conditioner lays area's engineering design device, includes detector main part (1), be provided with probe (2) on detector main part (1), probe (2) outside is provided with protecting crust (3), its characterized in that: a sealing part (4) is arranged in the protective shell (3), the protective shell (3) is sealed when the detector is not used, a drying part (5) is arranged in the detector main body (1), water vapor attached to the probe (2) is removed before the detector is used to prevent the water vapor from affecting a detection result, a cleaning part (6) is arranged in the sealing part (4), and the water vapor and dust on the probe (2) are cleaned when the sealing part (4) is reset after the detector is used;

the sealing piece (4) comprises a sealing sleeve (41) movably arranged in the protective shell (3), a sealing plate (42) is arranged at the top end of the sealing sleeve (41), a mounting plate (43) is arranged in the detector main body (1), a driving motor (44) is arranged on the mounting plate (43), a lead screw (45) is arranged at the output end of the driving motor (44), the sealing sleeve (41) is in threaded connection with the lead screw (45), and the sealing sleeve (41) is driven to move in the protective shell (3) when the lead screw (45) rotates;

the drying part (5) comprises a ventilation ring (51) arranged in the detector main body (1), a connecting pipe (52) is arranged on one side of the ventilation ring (51), fan blades (53) are arranged in the connecting pipe (52), a supporting plate (54) is arranged in the detector main body (1), a driving motor (55) is arranged on the supporting plate (54), and the output end of the driving motor (55) is in transmission connection with the fan blades (53);

the probe is characterized in that the top of the ventilation ring (51) is connected with a ventilation pipe (56), a ventilation groove (57) is formed in the sealing sleeve (41), the ventilation pipe (56) is movably inserted into the ventilation groove (57), an air duct (58) communicated with the ventilation groove (57) is formed in the sealing plate (42), an electric heating wire (59) is arranged in the ventilation ring (51), and air flow generated by rotation of the fan blade (53) is heated by the electric heating wire (59) and blown to the surface of the probe (2) through the ventilation pipe (56), the ventilation groove (57) and the air duct (58).

2. A radiant air conditioning floor area engineering design device as claimed in claim 1, characterized by: the air duct (58) is gradually narrowed from the outer side of the closing plate (42) to the center.

3. An apparatus for the engineering of a radiant air conditioning installation area as claimed in claim 2, wherein: the utility model discloses a probe cleaning device, including seal plate (42), has seted up movable groove (61) in seal plate (42), cleaning member (6) are including activity setting fly leaf (62) in movable groove (61), spout (63) have been seted up on fly leaf (62), spout (63) internalization is provided with ejector pin (64), ejector pin (64) both sides are provided with guide bar (65), guide bar (65) activity sets up in fly leaf (62), the guide bar (65) outside is provided with elastic component (66), guide way (7) have been seted up on protecting crust (3) when seal plate (42) rises, ejector pin (64) drive fly leaf (62) tip through cooperating with guide way (7) and compress tightly probe (2), and then clean probe (2) outside at its ascending in-process.

4. A radiation air-conditioning laying area engineering design device as claimed in claim 3, characterized in that: the elastic member (66) is a spring.

5. A radiant air conditioning floor area engineering design device as claimed in claim 4, characterized by: guide way (7) are including offering first perpendicular groove (71) and the perpendicular groove of second (72) at protecting crust (3) inner wall, chute (73) have all been seted up at first perpendicular groove (71) and the perpendicular groove of second (72) both ends during closing plate (42) descend, ejector pin (64) tip activity is in first perpendicular groove (71) when closing plate (42) ascend, ejector pin (64) activity is in the perpendicular groove of second (72), the degree of depth that the perpendicular groove of second (72) is less than the degree of depth of first perpendicular groove (71).

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