DE202018105135U1 - Nozzle design - Google Patents

Abstract

A nozzle construction for spraying high flow air and a liquid, comprising:
an air flow tube having an air flow passage for flowing the high flow rate air;
a rotatable rotation unit encased in the air flow tube;
- A load element, which is arranged on the rotation member to increase the load of the rotation unit and thereby increase the torque of the rotation unit;
a spray element mounted on the rotary member;
- A jet pipe which is fixed to the rotary unit. The beam has a beam channel. The jet is connected to the airflow tube. The air flow channel is connected to the jet channel. The jet channel has an outlet end. The jet channel has an ejection path at the outlet ends. The ejection path is at an acute angle to an axis of the air flow tube; and
a liquid flow tube having, opposite to each other, a liquid inlet end and a liquid outlet end. The liquid inlet end is located outside the air flow tube, and the liquid outlet end is disposed through the air flow tube to the air flow channel, and the air flow channel extends to the outlet end of the jet channel, spraying the liquid from the liquid outlet end and mixing it with high flow rate air for atomization. At this time, the high-flow air is sprayed from the air flow passage toward the outlet end, so that the exhaust end rotates out of the jet toward the axis due to the eccentric force. As the rotation unit rotates, the spray element is also rotated to form an airflow. The outlet end is located in the flow path of the air flow.

Description

[Technical part]

This invention relates to a nozzle construction, and more particularly to a nozzle construction having a load element and a spray element.

[State of the art]

With the improvement of the quality of life in the area of clothing, food, accommodation and entertainment, the means of transport have also evolved from bicycle and motorcycle to motor vehicle and recreational vehicle. As a result of the operation of such a vehicle on roads this is inevitably polluted by sand and dust. Therefore, the vehicle should be cleaned and sprayed after a few trips to keep the body clean, which is why many car owners in the spare time to clean their vehicles in a car wash. When cleaning the body, the manufacturer uses a foam-impregnated detergent to brush the body, and the foam of the cleaning agent is then rinsed by the jet of water from a water lance. However, during cleaning, the pressure of the water jet of the water lance is often insufficient, so that the dust on the bodywork is not easy to remove and stains from dust and sand remain after cleaning the vehicle.

Therefore, some manufacturers have developed a pressure spray gun to improve the cleaning performance of the spray gun or air spray gun by using high pressure air. The spray gun or air spray gun is connected by a tee to a handle, a liquid cylinder, and a nozzle, and the bottom of the handle is connected by a hose to an air compressor. To create the so-called Venturi effect, the handle controls the high pressure air from the air compressor into the T-piece to force the liquid out of the liquid cylinder and then sprayed out through the nozzle.

However, the pressure spray gun or Luftsprühpistole has only a small spray area. If a user wants to perform a large-scale cleaning by means of the pressure spray gun or air spray gun at a high speed, it is easy to skip a part of the area to be cleaned due to the rapid rinsing process, so that this area remains unpurified. As a result, it takes the user a long time to repeat the same area repeatedly until an optimal cleaning effect can be achieved. Therefore, the developers now had to solve the question of how the overall cleaning power of the spray gun can be improved overall.

[Content of the utility model]

The present invention is a nozzle construction that solves the underlying technical problem of insufficient overall cleaning power in the air spray gun.

An example of the present invention relates to a nozzle construction for spraying high flow rate air and a liquid comprising an air flow tube, a rotating unit, a load element, a spray element, a jet tube and a liquid flow tube. The air flow tube has an air flow passage in which the air circulates at a high flow rate. The rotatable rotation unit is attached to the air flow tube. The load element is mounted on the rotary member to increase the weight of the rotary unit and its torque. The spray element is fixed to the rotation unit. The jet pipe is attached to the rotary unit having a jet channel and connected to the air flow tube. The air flow channel is connected to the jet channel. The jet channel has an outlet end and at the outlet end in turn a jet channel. The jet channel and the axis of the air flow tube are at an acute angle to each other. The liquid flow tube has a corresponding liquid inlet end and a liquid outlet end. The liquid inlet end is located outside the air flow tube, and the liquid outlet end enters the air flow channel through the air flow tube, the air flow channel extending to the outlet end of the jet channel, thereby exiting the liquid outlet end and mixing for high flow rate air atomization. At this time, the high-flow air is sprayed from the air flow passage toward the outlet end, so that the outlet end relatively rotates due to the eccentric force from the jet pipe to the axis. As the rotation unit rotates, the spray element is also rotated to form an airflow. The outlet end is located in the flow path of the air flow.

According to the nozzle construction as set forth in the above-mentioned example, the spray member and the load member are installed together on the rotation unit, and the spray member and load member are driven to rotate as the high-flow air flows through the jet pipe , At this time, the rotary spray member generates an air flow, and flows from the spray member to the outlet end to increase the liquid and high-velocity misting effect, or flows from the outlet end to the spray member to absorb the impurities adjacent to the outlet end. In addition, the load member increases the load of the rotary unit, so that the torque of the rotary unit is increased. In this way, in the arrangement of the spray element and the load element, the general cleaning power of the nozzle construction can be further improved.

The above description of the present invention and the following description of the embodiments are presented to illustrate the principles of the present invention and to further illustrate the scope of the patent application.

list of figures

• Cross-sectional exploded view of the nozzle construction as set forth in the first example of the present invention
• Function diagram of the
• Functional diagram of the nozzle construction as embodied in the second example of the present invention
• Functional diagram of the nozzle construction, as carried out in the third example of the present invention

[Embodiment]

Please refer and , Fig. 10 is a sectional exploded view of the nozzle construction as embodied in the first example of the present invention. is a functional diagram of the nozzle construction of ,

The nozzle construction 1 of the embodiment is used for spraying nebulized air and liquid at high speed. Nozzle design 1 For example, a cleaning spray gun can be used to clean a bodywork. Nozzle design 1 includes an air flow tube 10 , an air compressor 20 , a rotation unit 30 , a beam pipe 40 a liquid flow tube 50 , a liquid storage tank 60 and a load element 70 ,

The air flow pipe 10 has an air passage 11 , and the opposite ends of the air flow tube 10 have an air inlet end 12 or an air outlet end 13 , The inlet end 12 is with an air compressor 20 connected, which is used to ensure a high air flow rate.

The rotatable rotation unit 30 is on the air flow tube 10 appropriate. More precisely, the rotation unit has 30 a first end 31 and a second end 32 , and the rotation unit 30 has a passage 33 that is from the first end 31 to the second end 32 extends. The first end 31 is rotatable on the air flow tube 10 arranged so that a portion of the air flow tube 10 within the passage 33 located.

The jet pipe 40 is at the rotation unit 30 attached, and the jet pipe 40 has a jet channel 41 , A section of the jet pipe 40 stands with the air flow pipe 10 in contact, and the air flow channel 11 allows a kind of communication with the beam 41 , More specifically, the jet channel has an outlet end opposite 411 and a connection end 412 on. Through the connection from the connection end 412 with the air outlet 13 are the beam channel 41 and the air flow channel 11 connected with each other. The one from the air compressor 20 supplied high-flow air can from the inlet end 12 from sequentially through the air flow channel 11 and the beam channel 41 flow and from the outlet end 411 the beam channel 41 be ejected. More precisely, the jet pipe 40 includes a bent tubular body 42 and a combined tube body 43 , and the beam channel 41 extends through the bent tubular body 42 and the combined tube body 43 , The outlet end 411 is close to one end of the curved tubular body 42 and removed from the connecting pipe body 43 arranged, and the connection end 412 is close to one end of the connecting pipe body 43 and away from the curved one pipe body 42 arranged. The connecting pipe body 43 is with the air flow tube 10 connect to. The outlet end 411 and the connection end 412 are not connected coaxially, so the ejection path A at an acute angle θ to the axis P of the air flow tube 10 lies when the high flow air from the outlet end 411 is ejected.

At the time of ejection, when the high-flow air through the jet channel 41 to the outlet end 411 flows, the high-flow air simultaneously generates a reaction force on the outlet end 411 , Since the outlet end 411 not on the axis P located and the ejection path A not parallel to the axis P is located when the reaction force on the outlet end 411 works, the outlet end 411 in an eccentrically loaded state, so that the beam 40 the rotation element 30 for common rotation drives. Will the high flow air from the outlet end 411 ejected, there is the ejection path A at an acute angle θ to the axis P of the air flow tube 10 , and the outlet end 411 is during the rotation of the beam 40 circular around the axis P emotional.

The fluid flow tube 50 has an opposite liquid inlet end 51 and a liquid outlet end 52 , The liquid outlet end 52 is outside the airflow tube 10 , and the liquid inlet end 51 is located in the liquid storage tank 60 , In addition, the air flow tube has 10 an annular side wall 14 that has an air flow channel 11 forms, and the annular side wall 14 has a through hole 141 that with the air flow channel 11 communicates. More precisely, the flow tube 50 passes through the through hole 141 through into the airflow channel 11 and the liquid flow tube 50 extends towards the outlet end 411 of the beam 41 so that the liquid outlet end 52 outside the air flow tube 10 located. The liquid storage tank 60 stores a cleaning fluid 2 such as water, soap liquid, cleaning liquid, etc., and the liquid flow tube 50 pulls the cleaning fluid 2 through the liquid inlet end 51 , In addition, the shower structure includes 1 Furthermore, a stop part 80 at the through hole 141 is arranged to the resulting gap between the liquid flow tube 50 and the through hole 141 seal, and to prevent the air in the air flow channel 11 exits through the gap.

The load element 70 is for example a compression spring; the load element 70 is at the second end of the rotation unit 30 attached and covers the jet pipe 40 down to the load of the rotation unit 30 to increase and thereby in turn the torque of the rotary member 30 to increase. The arrangement in the present embodiment, in which as a load element 70 a compression spring is not intended to limit the present invention. In other embodiments, other components such as bands may be used.

In the present embodiment, the nozzle construction includes 1 another nozzle screen 90 , The nozzle screen 90 has a third end 91 , a fourth end 92 and a nozzle opening 93 on. The third end 91 and the fourth end 92 are located on opposite sides of the nozzle screen 90 , and the nozzle opening 93 is located at the fourth end 92 , and the opening outer diameter W1 the third end 91 from the nozzle screen 90 is smaller than the opening diameter W2 of the fourth end 92 , The nozzle screen 90 is through the third end 91 at the outlet of the air outlet 13 of the air flow tube 10 so encased that the rotation element 30 , the jet pipe 40 and the load element 70 all in the nozzle screen 90 are located. The outlet end 411 of the jet pipe 40 corresponds to the nozzle opening 93 , In addition, while the outlet end 411 of the jet pipe 40 around the axis P turns, the maximum rotation diameter of the outlet end 411 smaller than the diameter of the nozzle opening 93 so that the outlet end 411 the nozzle opening 93 does not bother and the jet pipe 40 can turn smoothly. In addition, the nozzle shield protects 90 the jet pipe 40 also from damage by external forces.

The high flow rate air sequentially passes through the inlet end 12 in the air flow path 11 and the beam channel 41 and enters through the liquid outlet end 52 the liquid flow tube 50 through the beam channel 41 through, just becomes a Venturi effect at the liquid outlet end 52 the liquid flow tube 50 in the jet channel 41 generated so that the pressure at the liquid outlet end 52 less than the pressure at the liquid inlet 51 , As a result, the cleaning liquid becomes 2 in the liquid storage tank 60 due to the influence of the pressure difference between the liquid outlet end 52 and the liquid inlet end 51 from the liquid inlet end 51 to the liquid outlet end 52 sucked in and then flows out. Next is the cleaning fluid 2 coming from the liquid outlet end 52 is discharged with the high-flow air in the jet 41 mixed to be atomized, and then from the outlet end with the high flow rate air 411 pushed out. While the cleaning fluid 2 and the high flow rate air from the outlet end 411 that will be expelled outlet 411 around the axis P rotated so that the mixed with air and liquid wash water jet is continuously ejected in a vortex form. Therefore, the spray area of the nozzle construction 1 be increased by the swirling spray water jet to increase the cleaning area. On the other hand, the nozzle screen limits 90 the spray area of the outlet end 411 to prevent the spray area of the wash water jet from becoming too large and uncontrolled, which could affect the user's work.

In addition, since the load element 70 on the rotation element 30 is mounted, the load of the rotary member 30 increases, in turn, the torque of the rotary element 30 increase, so that the general cleaning power of the nozzle construction 1 can be improved. In detail we refer to the following table. The following table compares the water supply through nozzle design 1 in the present embodiment with the nozzle construction 1 without load element 70 with air volume, number of revolutions without water supply, number of revolutions and water consumption time for the same amount of water. Therefore, it can be seen that the nozzle construction 1 of the present embodiment in comparison with the nozzle construction 1 without load element 70 has better performance in terms of number of revolutions without water supply, number of revolutions with water supply and water consumption time. Therefore this is the load element 70 capable of the general cleaning power of the nozzle construction 1 to improve. Rotating nozzle construction with load element Rotating nozzle construction without load element Water tank capacity (ml) 600 600 Air volume (liters / min) 125 102 Number of revolutions without water supply (R / Min) 4100 6600 Number of revolutions with water supply (R / Min) 3900 6300 Water consumption Time 12 minutes 49 seconds 4 minutes 37 seconds

In addition, the nozzle construction includes 1 the embodiment still a spray element 100 , a combination element 110 and an air cap 120 , The rotation unit 30 includes on the outer surface of a male part 34 , a mounting section 35 and an extension 36 that are interconnected. The mounting section 35 the rotation unit 30 is located between the male part 34 and the extension 36 , The first end 31 is located at the end where the male part 34 from the mounting section 35 is removed, and the second end 32 is at the end where the extension 36 from the mounting section 35 is removed. The plug-in part 34 the rotation unit 30 is at the air flow tube 10 jacketed. The load element 70 and the spray element 100 are coaxial and each at the extension 36 and the mounting section 35 appropriate.

In addition, the nozzle screen has 90 also a flow opening 94 between the third end 91 and the fourth end 92 on. The combination element 110 is at the air flow tube 10 sheathed and has an air inlet 1101 on, and the air intake 1110 corresponds to the flow opening 94 , The air hood 120 is located in the nozzle screen 90 and has an air duct 1201 and an air outlet 1202 that with the air duct 1201 combines. The air hood 120 is on the air flow tube 10 opposite one end of the air outlet 1202 jacketed. More precisely, the air hood 120 is opposite one end of the air outlet 1202 on the combination element 110 mounted to the air flow tube 10 to be sheathed. The combined tubular body 43 of the jet pipe 40 , the spray element 100 , the rotation element 30 and the load element 70 are inside the air duct 1201 the air hood 120 arranged.

As in is shown in the embodiment during the rotation of the rotary member 30 also the spray element 100 turned around, allowing a flow of air through the opening 94 passes through the air inlet 1101 into the air hood 120 enters and from the air duct 120 along the first direction D1 over the air duct 1201 and the air outlet 1202 exit. Because the air hood 120 has an air-collecting effect, the air flow can control the mixing and atomizing degree of the high-flow air and the cleaning liquid 2 further improve, reducing the overall cleaning power of the nozzle construction 1 is improved. In addition, the air hood provides 120 not only the air-collecting effect safe, but also ensures that the load element 70 when turning do not wobble excessively.

In this embodiment, flows from the spray element 100 generated air flow from the air inlet 1101 to the air outlet 1202 along the first direction D1 , It is not limited to that, see , Fig. 10 is a schematic view showing the operation of the nozzle construction according to the second embodiment of the present invention. In the present embodiment, the direction of the spray element 100 ' generated air flow relative to the spray element 100 in the vice versa. Strictly speaking, the rotation unit drives 30 ' the spray element 100 ' for rotation, then enters an air flow from the air outlet 1202 ' into the air hood 120 ' and then the airflow flows through the air channel 1201 ' , the air intake 1101 ' and the opening 94 ' along the second direction D2 and exits the nozzle screen 90 ' out. Because the air hood 120 ' has an air-collecting effect, the ability of the nozzle construction 1' be further increased to the impurities near the exit end 411 ' of the beam 41 ' absorb, thereby increasing the overall cleaning power of the nozzle construction 1' is improved.

In the above embodiment, the load element and the spray element are used to improve the general cleaning power of the nozzle construction, but it is not limited thereto, see , Fig. 10 is a schematic view showing the operation of the nozzle construction according to the third embodiment of the present invention.

The nozzle construction 1" This embodiment also includes a torque control element 130 ' , The torque control element 130 ' is, for example, a brush construction. The torque control element 130 ' is on the combination element 110 ' and in the air duct 1201 " the air hood 120 ' arranged. The torque control element 130 ' touches the rotation element 30 " , The other detailed components of the nozzle construction 1" are similar to the detailed components of the nozzle construction 1 of the embodiment in the and therefore will not be described again.

In this embodiment, while the rotation member 30 " turns to the torque control element 130 ' to drive, the torque control element 130 ' a resistance on the rotation unit 30 " ago, so that the torque of the rotation unit 30 " increases. This will provide the general cleaning power of the nozzle design 1" further improved.

According to the nozzle construction of the above embodiment, high-flow air flows through the jet pipe, and the spray member and the load member are simultaneously driven to rotate because the spray member and the load member are installed in common on the rotation unit. The rotating spray element generates an air flow. The air flow flows from the spray element to the outlet end, so that the fogging effect of the mixture of liquid and air is increased at a high flow rate. Alternatively, the airflow flows from the outlet end towards the spray element to absorb contaminants adjacent to the outlet end. In addition, the load member increases the load of the rotary unit, so that the torque of the rotary member is increased. In this way, by the arrangement of the spray element and the load element, the general cleaning power of the nozzle construction can be further improved.

In addition, by the arrangement of the torque control element provided on the combination element, the torque of the rotation unit can be increased, thereby further improving the general cleaning performance of the nozzle structure.

Although the present invention has been defined by the present preferred embodiments. Anyone familiar with similar technologies may make some changes and refinements without departing from the spirit and claim of this utility model. Therefore, the utility model protection field of the present invention is based on the definition of the claims attached to this specification.

LIST OF REFERENCE NUMBERS

1, 1 ', 1 "

Nozzle design

2

cleaning supplies

10

Airflow pipe

11

Air flow channel

12

inlet end

13

outlet

14

Annular sidewall

141

perforation

20

air compressor

30, 30 '

rotation unit

31

First end

32

Second end

33

passage

34

male member

35

mounting portion

36

renewal

40

lance

41, 41 '

beam channel

411.411 '

output end

412

bond end

42

Bent tube body

43

Combined tubular body

50

Liquid flow pipe

51

liquid inlet

52

liquid outlet

60

Liquid storage tank

70

Last parts

80

stop part

90, 90 '

jet screen

91

Third end

92

Fourth end

93

Nozzle opening

94, 94 '

Flow opening

100, 100 '

spraying

110, 110 "

combiner

1101, 1101 '

air intake

120, 120 ', 120 "

air hood

1201, 1201 ', 1201 "

air duct

1202, 1202 '

air outlet

130 '

Torque control

A

discharge path

P

axis

Θ

acute angle

W1, W2

outer diameter

D1, D2

direction

141

perforation

20

air compressor

30

rotation unit

31

First end

32

Second end

33

passage

34

male member

35

mounting portion

36

renewal

40

lance

41

beam channel

411

output end

412

connecting end

42

Bent tube body

43

Combined tubular body

50

Liquid flow pipe

51

liquid inlet

52

liquid outlet

60

Liquid storage tank

70

load element

80

stop part

90

jet screen

91

Third end

92

Fourth end

93

Nozzle opening

94

Flow opening

100

spraying

110

mounting element

1101

air inlet

120

air hood

1201

air duct

1202

air output

W1, W2

outer diameter

Claims (15)

A nozzle construction for spraying high flow rate air and a liquid comprising: an air flow tube having an air flow passage for flowing the high flow rate air; a rotatable rotation unit encased in the air flow tube; - A load element, which is arranged on the rotation member to increase the load of the rotation unit and thereby increase the torque of the rotation unit; a spray element mounted on the rotary member; - A jet pipe which is fixed to the rotary unit. The beam has a beam channel. The jet is connected to the airflow tube. The air flow channel is connected to the jet channel. The beam channel has a Outlet. The jet channel has an ejection path at the outlet ends. The ejection path is at an acute angle to an axis of the air flow tube; and a liquid flow tube having, opposite to each other, a liquid inlet end and a liquid outlet end. The liquid inlet end is located outside the air flow tube, and the liquid outlet end is disposed through the air flow tube to the air flow channel, and the air flow channel extends to the outlet end of the jet channel, spraying the liquid from the liquid outlet end and mixing it with high flow rate air for atomization. At this time, the high-flow air is sprayed from the air flow passage toward the outlet end, so that the exhaust end rotates out of the jet toward the axis due to the eccentric force. As the rotation unit rotates, the spray element is also rotated to form an airflow. The outlet end is located in the flow path of the air flow. Nozzle construction after Claim 1 wherein the rotation unit has a first end and a second end opposite each other, and the rotation unit has a passage extending from the first end to the second end. The first end is rotatably disposed on the air flow tube so that a portion of the air flow tube and a portion of the jet tube are within the passageway. The outlet end of the jet pipe is outside the passageway. Nozzle construction after Claim 2 wherein the load element is on a side where the spray element is remote from the first end. The load element encloses the jet pipe. Nozzle construction after Claim 3 , wherein the load element is a compression spring. The load element and the spray element are arranged coaxially on the rotation unit. Nozzle construction after Claim 2 wherein the rotation unit on the outer surface comprises a male part, a mounting part and an extension which are connected to each other. The mounting section is located between the male part and the extension. The first end is at the end where the male part is remote from the mounting portion, and the second end is at the end where the extension is away from the mounting portion. The male part is encased in the air flow tube. The load element is arranged on the extension. The spray element is encased in the mounting section. The nozzle construction after Claim 1 further includes an air vent. The air cap has an air duct and an air outlet that connects to the air duct. The air cap is encased in the air flow tube opposite one end of the air outlet. A part of the jet, the spray element, the rotation unit and the load element are arranged inside the air duct of the air cap. The nozzle construction after Claim 6 further comprises a combination element. The combination element is encased in the air flow tube. The air cap is mounted to the combination member opposite one end of the air outlet. The combination element has an air inlet to allow the flow of air from the air inlet to the air outlet. The nozzle construction after Claim 6 further comprises a combination element. The combination element is encased in the air flow tube. The air cap is mounted to the combination member opposite one end of the air outlet. The combination element has an air inlet for allowing the flow of air from the air outlet to the air inlet. The nozzle construction after Claim 7 or Claim 8 further comprises a torque control element, which is arranged on the combination element and is located in the air duct of the air cap. The torque control element touches the rotation element. The nozzle construction after Claim 6 further includes a nozzle screen. The nozzle screen has a nozzle opening. The nozzle screen is sheathed on the air flow tube opposite one end of the nozzle opening. The air cap is located inside the nozzle screen, and the outlet end corresponds to the nozzle opening. Nozzle construction after Claim 2 wherein the jet comprises a bent tubular body and a combined tubular body connected together. The outlet end is located on the bent tubular body. The combined tube body connects to the air flow tube. The nozzle construction after Claim 1 also includes an air compressor. The air flow tube has an air inlet end and an air outlet end opposite one another. The inlet end is connected to the air compressor, the air outlet end to the jet pipe. The nozzle construction after Claim 1 further includes a liquid storage tank. The liquid inlet end of the liquid flow tube is within the liquid storage tank. Nozzle construction after Claim 1 wherein the air flow tube has an annular side wall forming an air flow passage. The annular side wall has a through hole. The flow tube passes through the through hole. The nozzle construction after Claim 14 further comprises a stop member. The stopper member is disposed at the through hole. The flow tube passes through the stop member.

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