CN107869763B - Indoor unit of air conditioner - Google Patents

Abstract

The invention relates to an air-conditioning indoor unit, comprising: the air conditioner comprises a shell, a first air inlet, a second air inlet, a first lateral air outlet and a second lateral air outlet, wherein the first air inlet and the second air inlet are positioned at the upper part of the shell and are sequentially arranged from back to front; a heat exchange device configured to exchange heat with air flowing therethrough; the fan assembly is arranged on the front side of the heat exchange device and is configured to promote natural air entering from the second air inlet to flow to the heat exchange device and promote heat exchange air subjected to heat exchange by the heat exchange device to flow towards the first lateral air outlet and the second lateral air outlet respectively; and the first ion wind generating device and the second ion wind generating device are transversely arranged at the rear side of the heat exchange device side by side and are configured to enable natural air entering from the first air inlet to directly flow to the first lateral air outlet and the second lateral air outlet, so that the natural air and heat exchange air subjected to heat exchange through the heat exchange device are mixed at the first lateral air outlet and the second lateral air outlet.

Description

Indoor unit of air conditioner

Technical Field

The invention relates to the air conditioning technology, in particular to an air conditioner indoor unit.

Background

Generally, the air outlet mode of the wall-mounted air conditioner indoor unit is bottom air outlet, and the air sent by the air supply mode is directly blown to the human body. In addition, since all of the blown air is heat-exchanged air, the air blown by such an air conditioning indoor unit is not soft. Especially, considering that the air outlet area and the air outlet range of the lower air outlet are limited, the air outlet is concentrated, and in the refrigeration mode, the air outlet temperature of the air conditioner is too low, so that the air conditioner is very uncomfortable when being blown to a user, and air conditioner diseases are easily caused. Therefore, how to expand the air supply range of the indoor unit of the air conditioner and reduce the impact of local high-speed cold air flow to alleviate or even eliminate air conditioning diseases on the premise of meeting the requirements of indoor refrigerating capacity and refrigerating efficiency is a technical problem to be solved urgently by those skilled in the art.

Disclosure of Invention

An object of the present invention is to overcome at least one of the drawbacks of the prior art and to provide an indoor unit of an air conditioner that supplies soft, uniform, comfortable air and has a wide air supply range.

Another object of the present invention is to improve cooling/heating efficiency and cooling/heating effect of an indoor unit of an air conditioner.

Still another object of the present invention is to reduce noise during operation of an indoor unit of an air conditioner.

In order to achieve the above object, the present invention provides an indoor unit of an air conditioner, comprising:

the air conditioner comprises a shell, a first air inlet, a second air inlet, a first lateral air outlet and a second lateral air outlet, wherein the first air inlet and the second air inlet are positioned at the upper part of the shell and are sequentially arranged from back to front;

the heat exchange device is arranged in the shell and is configured to exchange heat with air flowing through the shell;

the fan assembly is arranged on the front side of the heat exchange device and is configured to enable the natural air entering from the second air inlet to flow to the heat exchange device and enable the heat exchange air subjected to heat exchange through the heat exchange device to flow towards the first lateral air outlet and the second lateral air outlet respectively through an air duct of the fan assembly; and

the first ion wind generating device and the second ion wind generating device are arranged on the rear side of the heat exchange device in a transverse direction side by side and are configured to enable natural air entering from the first air inlet to directly flow to the first lateral air outlet and the second lateral air outlet through the first ion wind generating device and the second ion wind generating device respectively through electric field force, so that the natural air and heat exchange air subjected to heat exchange through the heat exchange device are mixed at the first lateral air outlet and the second lateral air outlet.

Optionally, a partition wall is disposed on an inner side of the top wall of the housing, and the partition wall extends vertically downward from a position between the first air inlet and the second air inlet to a position between the first ion wind generating device and the heat exchanging device and between the second ion wind generating device and the heat exchanging device or to a front side of an air inlet of the first ion wind generating device and the second ion wind generating device, so as to separate natural air flowing from the first air inlet to the first ion wind generating device and the second ion wind generating device from natural air flowing from the second air inlet to the heat exchanging device.

Optionally, the housing comprises:

a rear case for constituting a rear portion of the cabinet;

a front panel connected to a front side of the rear case to constitute a front of the cabinet; and

the air conditioner comprises a rear shell, a front panel, two first side air ducts and two second side air ducts, wherein the two first side air ducts are arranged in parallel in the front-rear direction, the two second side air ducts are arranged in parallel in the front-rear direction, the first side air ducts and the second side air ducts are respectively located at two transverse ends between the rear shell and the front panel, and the first side air outlets and the second side air outlets are respectively formed at outer side ports of the two first side air ducts and the two second side air ducts.

Optionally, the air duct of the fan assembly has two lateral air duct outlets facing to the two lateral sides, and the lateral outer ends of the first ion air generating device and the second ion air generating device both have air outlets facing to the lateral outer sides; and is

The first side air duct at the front side and the second side air duct at the front side have inner side ports respectively connected with two lateral air duct outlets of the fan assembly, so that a first sealed air duct is formed among the second air inlet, the heat exchange device, the fan assembly, the first side air duct at the front side and the second side air duct at the front side; the inner side end ports of the first side air duct and the second side air duct on the rear side are respectively connected with the air outlets of the first ion wind generating device and the second ion wind generating device, so that a second sealed air duct which is completely separated from and independent of the first sealed air duct is formed among the first air inlet, the first ion wind generating device, the second ion wind generating device, the first side air duct on the rear side and the second side air duct on the rear side.

Optionally, the rear housing has a vertically extending body and upper and lower edge portions bent and extending forward from upper and lower ends of the body, respectively; and is

The first air inlet is formed at the rear of the upper edge, and the second air inlet is formed at the front of the upper edge.

Optionally, the indoor unit of an air conditioner further includes:

the first fan air guide channel and the second fan air guide channel respectively extend from two transverse sides of the fan assembly to the front parts of the first lateral air outlet and the second lateral air outlet in a bending mode so as to respectively guide air flowing to the first lateral air outlet and the second lateral air outlet through an air channel of the fan assembly; and

and the first ion wind guiding channel and the second ion wind guiding channel respectively extend to the rear parts of the first lateral air outlet and the second lateral air outlet in a bending way from the transverse outer ends of the first ion wind generating device and the second ion wind generating device so as to respectively guide the air flowing to the first lateral air outlet and the second lateral air outlet through the first ion wind generating device.

Optionally, the first fan air guide channel and the first ion air guide channel are both columnar, the first fan air guide channel extends along a first arc-shaped curve from inside to outside, and the first ion air guide channel extends along a second arc-shaped curve from inside to outside; and is

The second fan air guide channel and the first fan air guide channel are symmetrically arranged, and the second ion air guide channel and the first ion air guide channel are symmetrically arranged.

Optionally, the center of a circle of the first circular arc-shaped curve is located on the front side of the first circular arc-shaped curve, and the center of a circle of the second circular arc-shaped curve is located on the front side of the second circular arc-shaped curve; and is

The radius of the circle where the first circular arc-shaped curve is located is larger than that of the circle where the second circular arc-shaped curve is located.

Optionally, an inner side edge of a vertical bisection plane of the first lateral air outlet, which extends in a front-rear direction near the air conditioning indoor unit, is more forward than an outer side edge of the first lateral air outlet, which is far away from the vertical bisection plane, so that the first lateral air outlet faces the outer side of the casing in the front direction; and is

The second lateral air outlet and the first lateral air outlet are symmetrically arranged.

Optionally, the first ion wind generating device and the second ion wind generating device each include at least one discharge module, each discharge module includes a metal mesh and a plurality of discharge needles located inside the metal mesh and arranged in an array, wherein the discharge needles are arranged in the metal mesh, and each discharge module includes a plurality of discharge needles located inside the metal mesh and arranged in an array

The distance L between the needle tip of each discharge needle and the metal mesh is set to satisfy the condition that L is a L₁Wherein a is any constant in the range of 0.7 to 1.3, L₁In order to make the wind speed of the ion wind at the wind speed central point of the metal mesh reach the maximum wind speed V_maxAnd the distance between the needle point of the discharge needle and the metal mesh, and the wind speed central point of the metal mesh is the projection point of the needle point of the discharge needle on the metal mesh.

Optionally, the distance R between the tips of two adjacent discharge needles is set so that it satisfies: r ═ aR₁Wherein R is₁For the wind speed to reach the maximum wind speed V_maxB is any constant within the range of 0.3-0.7.

Optionally, each of the first ion wind generating device and the second ion wind generating device comprises a plurality of discharging modules which are sequentially arranged and connected in parallel or in series, and each discharging module comprises a metal mesh and a plurality of discharging needles which are located on the inner side of the metal mesh and arranged in an array; and is

The discharge needles of two adjacent discharge modules are arranged in a straight-line opposite mode or in a staggered mode.

The air conditioner indoor unit drives the heat exchange air subjected to heat exchange through the heat exchange device to flow to the two lateral air outlets through the fan assembly, and promotes natural air in an environmental space to flow to the two lateral air outlets through the ion wind generating device. Part of heat exchange air after heat exchange of the heat exchange device and natural air which is not subjected to heat exchange of the heat exchange device are mixed at the two lateral air outlets, so that soft, uniform and comfortable mixed air is formed. The mixed air only enables the user to feel cool but not cold, warm but not hot comfortable experience, and does not bring sensory stimulation to the user or damage the physical health of the user. Meanwhile, the air sent out by the two lateral air outlets can form the effect of air supply on the left front side and the right front side, so that the impact of local high-speed cold air flow is reduced, and the air supply range of the indoor unit of the air conditioner is expanded.

Furthermore, the air-conditioning indoor unit is driven by the fan assembly to send out heat exchange air, and is driven by the independent ion air generating device to introduce natural air, so that the air-conditioning indoor unit is ensured to have larger integral air quantity and air speed, further, on the premise of ensuring the comfort degree of a user, the requirement of the integral indoor refrigerating capacity is met, the balance of the indoor temperature is ensured, and the refrigerating/heating efficiency and the refrigerating/heating effect of the air-conditioning indoor unit are improved.

Furthermore, the ion wind generating device makes the particles in the air obtain kinetic energy by means of electric field force, so that soft, uniform and comfortable ion wind without local high-speed airflow is formed. Compared with a rotary air supply assembly (such as a fan), the ion wind generating device has the advantages of pressure loss, low energy consumption, low noise and the like, so that the overall noise of the air conditioner indoor unit during operation is reduced to a certain extent.

Furthermore, the thickness of the air-conditioning indoor unit in the front and back direction can be reduced by the special design that the two air inlets are arranged at the upper part of the shell, and the fan assembly, the heat exchange device and the two ion wind generating devices are sequentially arranged from front to back, so that the volume of the air-conditioning indoor unit in the standing and working processes is reduced, the higher requirements of a user on the installation space and the use space of the air-conditioning indoor unit are met, and the overall appearance of the air-conditioning indoor unit is improved.

Furthermore, because the two lateral air outlets of the indoor unit of the air conditioner are both towards the front of the outer side of the shell, the two lateral air outlets of the indoor unit of the air conditioner can form an encircling air supply effect, so that the air supply range of the indoor unit of the air conditioner is further expanded, cold air or hot air is prevented from being directly blown to a human body, the uniformity of indoor temperature is improved, the comfort level of the indoor unit of the air conditioner is further improved, and the use experience of a user is better.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic structural view of an indoor unit of an air conditioner according to an embodiment of the present invention;

fig. 2 is a schematic front view of an air conditioning indoor unit according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view taken along section line B-B in FIG. 2;

fig. 4 is a schematic structural exploded view of an air conditioning indoor unit according to an embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view taken along section line A-A in FIG. 2;

FIG. 6 is a schematic structural view of a discharge module of the ion wind generating apparatus according to an embodiment of the present invention;

fig. 7 is a schematic cross-sectional view of a discharge module according to an embodiment of the present invention.

Detailed Description

The embodiment of the invention provides an air conditioner indoor unit. Fig. 1 is a schematic configuration view of an air conditioning indoor unit according to one embodiment of the present invention, fig. 2 is a schematic front view of the air conditioning indoor unit according to one embodiment of the present invention, fig. 3 is a schematic cross-sectional view taken along a sectional line B-B in fig. 2, fig. 4 is a schematic structural exploded view of the air conditioning indoor unit according to one embodiment of the present invention, and fig. 5 is a schematic cross-sectional view taken along a sectional line a-a in fig. 2. Referring to fig. 1 to 5, an air conditioning indoor unit 1 according to an embodiment of the present invention includes a casing 10, a heat exchanging device 20 disposed in the casing 10, a fan assembly 30 disposed in front of the heat exchanging device 20, and a first ion wind generating device 40 and a second ion wind generating device 50.

The cabinet 10 has a first intake vent 121 and a second intake vent 122 located at an upper portion thereof and arranged in sequence from back to front, and a first lateral air outlet 112 and a second lateral air outlet 113 located at both sides of the cabinet 10, respectively. Specifically, in some embodiments of the present invention, the first and second lateral air outlets 112 and 113 may face both lateral sides of the cabinet 10. In some preferred embodiments of the present invention, the first and second lateral outlets 112 and 113 may face a lateral front of the cabinet 10. Accordingly, the wind sent out through the first and second lateral outlets 112 and 113 is blown toward the lateral front of the cabinet 10. That is, the air sent out from each air outlet can directly reach the normal moving area of the user, thereby forming the effect of air supply from the left front side and the right front side, weakening the limit on the installation position of the indoor unit 1 of the air conditioner, increasing the air supply angle of the indoor unit 1 of the air conditioner, enlarging the air supply range and improving the cooling/heating efficiency.

The heat exchanging device 20 is configured to exchange heat with air flowing therethrough to change the temperature of the air flowing therethrough into heat exchanging air (cold air or hot air). The fan assembly 30 is configured to cause the natural air entering from the second air inlet 122 to flow to the heat exchanging device 20, and to cause the heat exchanged air after heat exchange by the heat exchanging device 20 to flow towards the first lateral air outlet 112 and the second lateral air outlet 113 via the air duct of the fan assembly 30, respectively. The first ion wind generating device 40 and the second ion wind generating device 50 are laterally disposed at the rear side of the heat exchanging device 20 side by side, and are configured to cause the natural air entering from the first air inlet 121 to directly flow to the first lateral air outlet 112 and the second lateral air outlet 113 via the first ion wind generating device 40 and the second ion wind generating device 50, respectively, by an electric field force, so that the natural air and the heat exchanged air after heat exchange by the heat exchanging device 20 are mixed at the first lateral air outlet 112 and the second lateral air outlet 113. It should be emphasized that the natural air referred to in the present invention means air that has not been heat-exchanged by the heat exchanging device 20, i.e. the ambient air of the ambient space where the indoor unit 1 of the air conditioner is located. The heat exchange air referred to in the present invention means air after heat exchange by the heat exchange device 20, and when the indoor unit 1 of the air conditioner is in a heating mode, the heat exchange air may be hot air, and when the indoor unit 1 of the air conditioner is in a cooling mode, the heat exchange air may be cold air.

After the partial heat exchange air after the heat exchange of the heat exchange device 20 and the natural air which is not subjected to the heat exchange of the heat exchange device 20 are mixed at the two lateral air outlets, soft, uniform and comfortable mixed air can be formed. The mixed air only enables the user to feel cool but not cold, warm but not hot comfortable experience, and does not bring sensory stimulation to the user or damage the physical health of the user. For example, in summer, when the indoor temperature of the air-conditioning indoor unit 1 is 26 to 35 ℃ for cooling, the temperature of the cooling air blown out is about 18 ℃. However, after natural air and 18 ℃ refrigerating air are mixed through the ion wind generating device, the outlet air temperature can be raised to about 23 ℃, and the 23 ℃ refrigerating wind is softer and more comfortable than the 18 ℃ refrigerating wind and is closer to the comfort degree of a human body. Meanwhile, the air sent out by the two lateral air outlets can form the effect of air supply on the left front side and the right front side, so that the impact of local high-speed cold air flow is reduced, and the air supply range of the indoor unit 1 of the air conditioner is expanded.

Meanwhile, the air-conditioning indoor unit 1 of the invention is driven by the fan assembly 20 to send out heat exchange air, and is driven by the single ion air generating device 40 to introduce natural air, so that on one hand, the air-conditioning indoor unit 1 is ensured to have larger integral air quantity and air speed, the requirement of indoor integral refrigerating capacity is met on the premise of ensuring the comfort of users, the balance of indoor temperature is ensured, and the refrigerating/heating efficiency and the refrigerating/heating effect of the air-conditioning indoor unit 1 are improved; on the other hand, the ion wind generating device relies on the electric field force to make the particles in the air obtain kinetic energy, so as to form soft, uniform and comfortable ion wind without local high-speed airflow (since the generating principle of the ion wind is easily obtained and known by those skilled in the art, the description is omitted here). Compared with a rotary air supply assembly (such as a fan), the ion wind generating device has the advantages of pressure loss, low energy consumption, low noise and the like, so that the overall noise of the air conditioner indoor unit 1 during operation is reduced to a certain extent. Meanwhile, the ion wind generated by the ion wind generating device is not generated by pressure, but is a soft wind close to nature generated by electric field force, so that the comfort level of the air-conditioning indoor unit 1 can be further improved.

In addition, it should be noted that, according to the invention, the two air inlets are arranged at the upper part of the casing, and the fan assembly 30, the heat exchange device 20 and the two ion wind generating devices are sequentially arranged from front to back, so that the thickness of the indoor unit 1 of the air conditioner in the front and back directions can be reduced, and therefore, the volume of the indoor unit 1 of the air conditioner during standing and working operation can be reduced, so as to meet the higher requirements of users on the installation space and the use space of the indoor unit 1 of the air conditioner, and the overall appearance of the indoor unit 1 of the air conditioner can be improved.

In summary, the air-conditioning indoor unit 1 according to the embodiment of the present invention is designed and reasonably arranged in a special way for the structures and positions of the air inlet, the air outlet, the heat exchanging device 20, the fan assembly 30, and the two ion wind generating devices, and the ion wind blowing technology staying on the theoretical level for a long time is improved in an original way, so that the ion wind blowing technology is perfectly combined with the fan air blowing components, and the technical problems of small air blowing range, large noise, poor experience effect, poor appearance effect, and the like in the prior art are solved with a simple structure. Meanwhile, the technical scheme of the invention has better realizability and economic value, is an innovation of the air supply form of the air conditioner and has better popularization value.

The ion wind generating device can ionize air to generate a large amount of charged particles, and the charged particles can adsorb solid particles, dust, pollutants and the like and then move towards a certain direction under the action of electric field force. The ion wind is formed by high voltage electric field, so it has high effect of sterilizing and decomposing harmful gas pollutant.

In some embodiments of the present invention, referring to fig. 3 and 4, the fan assembly 30 may include two centrifugal fans (e.g., a first centrifugal fan 31 and a second centrifugal fan 32) arranged side by side in a transverse direction and a front liner 34 connected to front portions of the two centrifugal fans, wherein the front liner 34 and the volutes of the two centrifugal fans together define an air duct out of the fan assembly 30. Specifically, the first centrifugal fan 31 and the second centrifugal fan 32 have their respective volutes and centrifugal impellers accommodated in the volutes, respectively. An air inlet is formed in one side, facing the heat exchange device 20, of the volute, the front liner plate 34 is arranged on one side, facing away from the heat exchange device 20, of the volute, and the front liner plate 34 and the volutes of the two centrifugal fans form an air channel of the fan assembly 30 together. The first centrifugal fan 31 and the second centrifugal fan 32 may be forward-direction centrifugal fans or backward-direction centrifugal fans.

Further, the heat exchanging device 20 may be a flat plate evaporator to improve heat exchanging efficiency and reduce the thickness of the indoor unit 1 in the front-rear direction, thereby reducing the volume of the indoor unit 1.

In some embodiments of the present invention, referring to fig. 5, the inner side of the top wall of the housing 10 is provided with a partition wall 144, and the partition wall 144 extends vertically downward from a position between the first air inlet 121 and the second air inlet 122 to a position between the first ion wind generating device 40 and the heat exchanging device 20 and between the second ion wind generating device 50 and the heat exchanging device 20 or to a front side of the air inlets of the first ion wind generating device 40 and the second ion wind generating device 50, so as to separate natural air flowing from the first air inlet 121 to the first ion wind generating device 40 and the second ion wind generating device 50 from natural air flowing from the second air inlet 122 to the heat exchanging device 20. Therefore, mutual interference between the natural air flowing to the first ion wind generating device 40 and the second ion wind generating device 50 and the natural air flowing to the heat exchanging device 20 can be avoided, and phenomena such as turbulent flow, turbulent flow or mixed flow can be avoided, so that the air inlet speed of the air-conditioning indoor unit 1 is increased, and the air outlet speed of the air-conditioning indoor unit is increased.

In some embodiments of the present invention, referring to fig. 4, the cabinet 10 includes a rear case 14, a front panel 13, and two first side air ducts 151 and two second side air ducts 152 arranged side by side in the front-rear direction. The rear case 14 serves to constitute a rear portion of the cabinet 10. The front panel 13 is disposed at a front side of the rear case 14 to constitute a front portion of the cabinet 10. The first side air duct 151 and the second side air duct 152 are respectively located at two lateral ends between the rear casing 14 and the front panel 13, that is, the first side air duct 151 and the second side air duct 152 are both located in a space defined between the rear casing 14 and the front panel 13 and are respectively located at two lateral ends of the space. The outer ports of the two first side air ducts 151 and the two second side air ducts 152 form a first side air outlet 112 and a second side air outlet 113, respectively. That is, the outer ports of the two first side air ducts 151 form the first side air outlet 112 together, and the outer ports of the two second side air ducts 152 form the second side air outlet 113 together.

It is emphasized that the outside ports of the first and second side wind scoops 151 and 152 mean their respective ports exposed to the outside of the cabinet 10, and accordingly, the first and second side wind scoops 151 and 152 also have inside ports hidden inside the cabinet 10, respectively.

Further, a fixing bracket 80 for fixing the heat exchanging device 20 may be disposed between the rear housing 14 and the heat exchanging device 20, and the heat exchanging device 20 and the fixing bracket 80, and the fixing bracket 80 and the rear housing 14 may be fixed together by screw connection, clamping connection, or other suitable connection methods.

In some embodiments of the present invention, the air duct of the fan assembly 30 has two lateral air duct outlets facing to both lateral sides, and the lateral outer ends of the first ion wind generating device 40 and the second ion wind generating device 50 each have an air outlet facing to the lateral outer side. The inner side ports of the first side air duct 151 and the second side air duct 152 on the front side are respectively connected to two lateral air duct outlets of the fan assembly 30, so as to form a first sealed air duct between the second air inlet 122, the heat exchanging device 20, the fan assembly 30, the first side air duct 151 on the front side and the second side air duct 152 on the front side. The inner side ports of the first side air duct 151 and the second side air duct 152 at the rear side are respectively connected to the air outlets of the first ion wind generating device 40 and the second ion wind generating device 50, so that a second sealed air duct completely separated and independent from the first sealed air duct is formed among the first air inlet 121, the first ion wind generating device 40, the second ion wind generating device 50, the first side air duct 151 at the rear side, and the second side air duct 152 at the rear side. Therefore, heat exchange air inside the indoor unit 1 of the air conditioner and natural air are not interfered with each other and not influenced with each other, and therefore the condition that disturbance is generated among air flows to influence the flow direction and the flow speed of the air flows is avoided.

Specifically, two lateral air duct outlets of the air duct of the fan assembly 30 are respectively used for supplying air to front portions of the first lateral air outlet 112 and the second lateral air outlet 113, and the two lateral air duct outlets can be respectively volute air outlets of the first centrifugal fan 31 and the second centrifugal fan 32. The air outlets of the first ion wind generating device 40 and the second ion wind generating device 50 are respectively used for supplying air to the rear parts of the first lateral air outlet 112 and the second lateral air outlet 113. Specifically, the first side air duct 151 and the second side air duct 152 on the front side may be respectively fixed to the fan assembly at the inner ports thereof by screws, clamping, or other suitable means, and the first side air duct 151 and the second side air duct 152 on the rear side may be respectively fixed to the two ion wind generating devices at the inner ports thereof by screws, clamping, or other suitable means.

In some embodiments of the present invention, referring to fig. 4, the rear case 14 has a body 141 extending vertically, and upper and lower edges 142 and 143 extending forward from upper and lower sides of the body 141. The first intake vent 121 may be formed at the rear of the upper edge portion 142, and the second intake vent 122 may be formed at the front of the upper edge portion 142. This simplifies the structure of the housing 10 and makes the whole housing more beautiful. Specifically, the body 141 may be provided with a hanging hole for hanging the indoor unit 1 of the air conditioner on a wall. The first air inlet 121 and the second air inlet 122 each include a plurality of uniformly distributed ventilation holes to ensure the uniformity of the inlet air.

In some embodiments of the present invention, referring to fig. 3 and 4, the air conditioning indoor unit 1 further includes a first fan air guiding passage 61, a second fan air guiding passage 62, a first ion air guiding passage 63, and a second ion air guiding passage 64. The first fan guiding duct 61 and the second fan guiding duct 62 respectively extend from two lateral sides of the fan assembly 30 to the front portions of the first lateral air outlet 112 and the second lateral air outlet 113 in a bending manner, so as to respectively guide air flowing to the first lateral air outlet 112 and the second lateral air outlet 113 through the air duct of the fan assembly 30. The first ion wind guiding channel 63 and the second ion wind guiding channel 64 respectively extend from the lateral outer ends of the first ion wind generating device 40 and the second ion wind generating device 50 to the rear portions of the first lateral wind outlet 112 and the second lateral wind outlet 113, so as to respectively guide the air flowing to the first lateral wind outlet 112 via the first ion wind generating device 40 and the air flowing to the second lateral wind outlet 113 via the second ion wind generating device 50. That is, the first fan guiding duct 61 and the second fan guiding duct 62 are respectively communicated with the front half parts of the first lateral air outlet 112 and the second lateral air outlet 113, and the first ion guiding duct 63 and the second ion guiding duct 64 are respectively communicated with the rear half parts of the first lateral air outlet 112 and the second lateral air outlet 113. Therefore, the air sent out from the two lateral air outlets can be blown to the left front side and the right front side of the shell, and independent air supply channels which are not influenced mutually can be formed between the fan assembly 30 and the ion wind generating device. The air conditioner indoor unit 1 can further ensure that an encircling air supply effect is formed, the resistance in the air flow flowing process can be reduced, and the air speed and the air volume of the two lateral air outlets are improved.

Specifically, the first and second fan guide air passages 61 and 62 may be respectively formed in the first and second side air funnels 151 and 152 at the front side, and the first and second ion air guide passages 63 and 62 may be respectively formed in the first and second side air funnels 151 and 152 at the rear side.

In some embodiments of the present invention, the first fan guiding air passage 61 and the first ion guiding air passage 63 are both in a cylindrical shape, the first fan guiding air passage 61 extends along a first circular arc-shaped curve from inside to outside, and the first ion guiding air passage 63 extends along a second circular arc-shaped curve from inside to outside. It will be understood by those skilled in the art that the terms "inner" and "outer" as referred to herein mean the interior and exterior of the enclosure 10, respectively. The second fan air guide channel 62 and the first fan air guide channel 61 are symmetrically arranged, and the second ion air guide channel 64 and the first ion air guide channel 63 are symmetrically arranged.

Further, the center of the circle of the first circular arc-shaped curve is located on the front side of the first circular arc-shaped curve, and the center of the circle of the second circular arc-shaped curve is located on the front side of the second circular arc-shaped curve. That is, each of the first circular arc-shaped curve and the second circular arc-shaped curve has a shape convexly curved rearward. Therefore, airflow can flow more smoothly, airflow resistance is further reduced, and the air speed and the air volume of the lateral air outlet are improved; and the first lateral air outlet 112 and the second lateral air outlet 113 can more easily form a looping air supply effect, so that the indoor unit 1 of the air conditioner is ensured to have the best comfort level.

Furthermore, the radius of the circle on which the first circular arc-shaped curve is positioned is larger than that of the circle on which the second circular arc-shaped curve is positioned. That is, the second circular arc-shaped curve has a shape convexly curved more rearward than the first circular arc-shaped curve. Therefore, the forward inclination degree of the natural air which is sent out by the two lateral air outlets and guided by the first ion air guiding channel 63 and the second ion air guiding channel 64 is larger than the forward inclination degree of the heat exchange air which is sent out by the two lateral air outlets and guided by the first fan air guiding channel 61 and the second fan air guiding channel 62, so that the natural air at the rear side and the heat exchange air at the front side are more favorably mixed in a cross mode, and the mixing effect of the two kinds of air is better.

In some embodiments of the present invention, referring to fig. 2, an inner side edge 1121 of the first lateral air outlet 112, which is close to a vertical bisecting plane S extending in the front-rear direction of the air conditioning indoor unit 1, is located more forward than an outer side edge 1122 of the first lateral air outlet 112, which is far from the vertical bisecting plane S, so that the first lateral air outlet 112 faces the outer side front of the casing 10. That is, the inner edge 1121 and the outer edge 1122 of the first lateral air outlet 112 are located at different positions in the lateral direction and the front-rear direction, the inner edge 1121 is closer to the vertically bisected plane of the air conditioning indoor unit 1 extending in the front-rear direction than the outer edge 1122 thereof, and the inner edge 1121 is located laterally forward of the outer edge 1122 thereof, so that the first lateral air outlet 112 is directed obliquely outward toward the front of the cabinet.

Further, the second lateral air outlet 113 and the first lateral air outlet 112 are symmetrically disposed. That is, the inner edge 1131 of the second lateral outlet 113 is more forward than the outer edge 1132 of the second lateral outlet 113. In other words, the inside edge 1131 and the outside edge 1132 of the second lateral air outlet 113 are located at different positions in the lateral direction and the front-rear direction, the inside edge 1131 is closer to the vertical bisecting plane S of the indoor unit 1 extending in the front-rear direction than the outside edge 1132, and the inside edge 1131 is located laterally forward of the outside edge 1132, so that the second lateral air outlet 113 faces obliquely outward toward the front of the cabinet.

Therefore, the two lateral air outlets of the indoor air conditioner 1 can respectively supply air towards the front of the transverse outer side of the casing 10 to form an encircling air supply effect, so that the air supply range of the indoor air conditioner 1 is further expanded, cold air or hot air is prevented from directly blowing to a human body, the uniformity of indoor temperature is improved, the comfort level of the indoor air conditioner 1 is further improved, and the use experience of a user is better.

Fig. 6 is a schematic exploded view of a discharge module of the ion wind generating device according to an embodiment of the present invention. In some embodiments of the present invention, referring to fig. 6, each of the first ion wind generating device 40 and the second ion wind generating device 50 includes at least one discharge module 410. Each discharge module 410 has a metal mesh 411 and a plurality of discharge needles 412 located inside the metal mesh 411 and arranged in an array. The needle point of the discharge needle 412 is close to the metal net 411, positive and negative high voltage electrodes are respectively applied on the discharge needle 412 and the metal net 411, the discharge needle 412 is equivalent to a radiation electrode for generating corona discharge, and the metal net 411 is equivalent to a receiving electrode.

It should be emphasized that the inner side referred to herein means a side of the metal net 411 toward the geometric center of the cabinet 10, and the outer side opposite to the inner side means a side of the metal net 411 toward the outside of the cabinet 10. That is, the flow direction of the ion wind generated by each discharge module 410 is from the inside to the outside, and the arrangement direction of the plurality of discharge needles 412 and the metal mesh 411 is the same as the flow direction of the ion wind.

Referring to fig. 7, in order to increase the blowing speed of the ion wind generating apparatus, a designer of the present invention has conducted a number of wind speed measurement experiments, and as a result, it has been found that the distance L between the tip of each discharge needle 412 and the metal mesh 411 is set to satisfy L ═ a L₁(wherein a is any constant in the range of 0.7-1.3, i.e. a can be 0.7, 0.8, 0.9, 1.0, 1.1, 1.2 or 1.3, L₁So that the wind speed of the ion wind at the wind speed center point of the metal mesh 411 reaches the maximum wind speed V_maxThe distance between the needle point of the discharge needle 412 and the metal mesh 411, and the wind speed center point of the metal mesh 411 is the projection point of the needle point of the discharge needle 412 on the metal mesh 411), on the one hand, the wind speed of the ion wind generated by the two ion wind generating devices can better meet the normal use requirement of a user, and on the other hand, the discharge needle 412 can be partially overlapped in the area of the metal mesh 411 generating effective ion wind to achieve the projection effect of the shadowless lamp, so that the ion wind distribution of the metal mesh 411 is more uniform.

In order to increase the amount of air supplied to the ion wind generating apparatus, the designer of the present invention has performed a large number of experiments for measuring the projection radius of the tips, and as a result of the experiments, it has been found that the distance R between the tips of two adjacent discharge needles 412 is set to satisfy the requirement of R ═ aR₁(wherein, R₁For the wind speed to reach the maximum wind speed V_maxB is the distance between the wind speed measuring point and the wind speed central point, and b is any one of the ranges of 0.3-0.7The constant, namely b can be 0.3, 0.4, 0.5, 0.6 or 0.7, and the value of a is the same as the above), the air volume of the ion air generated by the two ion air generating devices can better meet the normal use requirement of a user. Meanwhile, after the distance between two adjacent discharge needles 412 is specially designed, the mutual offset of wind speeds caused by too close distance between two adjacent discharge needles 412 can be avoided, and the reduction of wind volume and the uneven distribution of wind volume caused by too far distance between two discharge needles 412 can be avoided.

Therefore, the ion wind generating device can generate the ion wind with uniform and large wind quantity by reasonably designing the spatial position relationship between the discharge needles 412 and the metal mesh 411 and reasonably arranging the position relationship between the discharge needles 412, so that the wind speed, the wind quantity and the wind efficiency of the ion wind generating device are improved.

In some embodiments of the present invention, each of the first ion wind generating device 40 and the second ion wind generating device 50 includes a plurality of discharge modules 410 arranged in sequence and connected in parallel or in series, and each of the discharge modules 410 has a metal mesh 411 and a plurality of discharge needles 412 located inside the metal mesh 411 and arranged in an array. Therefore, a corona discharge phenomenon is generated between the discharge needle 412 in each discharge module 410 and the corresponding metal mesh 411, so that the ion wind can be accelerated for multiple times through the plurality of discharge modules 410, the superposition of the wind speed can be realized, and the higher wind outlet speed can be obtained. And negative pressure can be formed under the action of high-speed air outlet, so that the air inlet volume is further increased, and the air supply speed, the air supply volume and the air supply efficiency of the multi-stage ion air supply module are improved.

In some embodiments of the present invention, the discharge needles 412 of two adjacent discharge modules 410 are arranged in a straight pair, that is, the projections of the discharge needles 412 of each two adjacent discharge modules in the air outlet plane of the ion wind generating device coincide. Therefore, a larger and stronger electric field is generated in the region corresponding to the tip of each discharge needle 412, so that an ion wind with a higher local wind speed is generated in the region, and the ion wind blows on the user body and has a stronger wind feeling. In other words, this arrangement can obtain a local large wind speed near each wind speed center point of the metal mesh 411, so as to improve the wind feeling when the air-conditioning indoor unit 1 is driven by the ion wind generating device to supply wind alone.

In some alternative embodiments of the present invention, the discharge needles 412 of two adjacent discharge modules 410 are arranged in a staggered manner. One of the dislocation arrangement modes is as follows: the discharge needles 412 of every two adjacent discharge modules are arranged in a staggered manner in a direction perpendicular to the air outlet surface of the ion wind generating device 10, and the projections of the corresponding discharge needles 412 of every two adjacent discharge modules in the air outlet surface of the ion wind generating device 10 are on the same horizontal line (i.e., the discharge needles 412 of every two adjacent discharge modules are arranged in a staggered manner, but the heights of the corresponding discharge needles 412 are the same). Therefore, uniform soft wind can be generated in a plurality of linear regions in the horizontal direction, and the superposition of a plurality of discharge modules can form a larger and stronger electric field in the linear regions, so that the wind speed of the ion wind in the linear regions is relatively higher. Further, the projections of each group of three adjacent discharge needles formed by the discharge needles 412 of the plurality of discharge modules in the horizontal plane all form an isosceles triangle, so as to ensure that the ion wind generated by the ion wind generating device is distributed uniformly.

Another staggered arrangement mode is as follows: the discharge needles 412 of every two adjacent discharge modules are arranged in a staggered manner in the direction perpendicular to the air outlet surface of the ion wind generating device and in the vertical direction. Therefore, the ion wind generated by the ion wind generating device can be uniformly distributed in the wind outlet surface of the ion wind generating device, so that soft, uniform and large-wind-volume air supply can be realized under the conditions of low voltage, low electric field intensity and low power. That is, the discharge needles 412 of each two adjacent discharge modules 410 are staggered from each other, so that the gaps between the discharge needles 412 of each discharge module 410 can be filled. Accordingly, relatively uniform ion wind can be formed in the entire area of the expanded metal 411, and the entire amount of wind can be increased. Further, the projections of each group of three adjacent discharge needles formed by the discharge needles 412 of the plurality of discharge modules in the air outlet surface of the ion wind generating device all form an equilateral triangle, so as to ensure that the ion wind generated by the ion wind generating device is distributed more uniformly.

In some embodiments of the present invention, referring to fig. 6, each discharge module 410 further includes a housing 416, a conductive metal strip 413 having a plurality of conductive metal strips 414, and at least one PCB multi-layer board 415 electrically connected to the conductive metal strip 413 and perpendicular to the conductive metal strip 413. The upper end of the housing 416 is hollowed out or provided with a vent for air to enter the housing 416. The PCB multi-layer board 415 has front and rear insulating protective layers and a conductive layer between the two insulating protective layers, and the conductive layer is electrically connected to the conductive metal sheet 414. The bottom wall of the housing 416 is opened with a buckle 4161, and the metal conductive sheet 414 of the metal conductive strip 413 is buckled in the buckle 4161 of the housing 416.

The number of PCB multi-layer boards 415 may be one, which is substantially rectangular; or the number of PCB multi-layer boards 415 may be plural, each PCB multi-layer board 415 having an elongated strip shape extending perpendicular to the metal conductive strips 413.

The plurality of discharge needles 412 are uniformly distributed on the outer side of the at least one PCB multi-layer board 415 facing the metal mesh 411. Specifically, each PCB multi-layer board 415 is provided with a plurality of pin holes on the outer surface thereof for mounting the discharge needles 412. The aperture of the pinhole is slightly smaller than the diameter of the discharge needle 412 so that the pinhole is in interference fit with the discharge needle 412. The filling layer filled by the welding process is arranged around the pin hole inserted into the discharge needle 412, that is, the filling layer filled by the welding process is arranged around the discharge needle 412 of the pin hole, so as to ensure that the discharge needle 412 is well electrically connected with the conductive layer in the PCB multi-layer board 415, and simultaneously, the conductive layer can be strictly prevented from being exposed to the outside, thereby avoiding the phenomena of random discharge or sparking.

It should also be understood by those skilled in the art that, unless otherwise specified, terms used to indicate orientation or positional relationship in the embodiments of the present invention such as "upper," "lower," "inner," "outer," "vertical," "horizontal," "front," "rear," and the like are based on the actual usage state of the air conditioning indoor unit 1, and these terms are only used for convenience of description and understanding of the technical solutions of the present invention, and do not indicate or imply that the devices or components referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore, should not be interpreted as limiting the present invention.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been illustrated and described in detail herein, many other variations or modifications consistent with the principles of the invention may be directly determined or derived from the disclosure of the present invention without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should be understood and interpreted to cover all such other variations or modifications.

Claims (9)

1. An indoor unit of an air conditioner, comprising:

the air conditioner comprises a shell, a first air inlet, a second air inlet, a first lateral air outlet and a second lateral air outlet, wherein the first air inlet and the second air inlet are positioned at the upper part of the shell and are sequentially arranged from back to front;

the heat exchange device is arranged in the shell and is configured to exchange heat with air flowing through the shell;

the fan assembly is arranged on the front side of the heat exchange device and is configured to enable the natural air entering from the second air inlet to flow to the heat exchange device and enable the heat exchange air subjected to heat exchange through the heat exchange device to flow towards the first lateral air outlet and the second lateral air outlet respectively through an air duct of the fan assembly; and

the first ion wind generating device and the second ion wind generating device are arranged on the rear side of the heat exchange device in a transverse direction side by side, and are configured to enable natural air entering from the first air inlet to directly flow to the first lateral air outlet and the second lateral air outlet through the first ion wind generating device and the second ion wind generating device respectively through electric field force, so that the natural air and heat exchange air subjected to heat exchange through the heat exchange device are mixed at the first lateral air outlet and the second lateral air outlet;

the first ion wind generating device and the second ion wind generating device respectively comprise at least one discharging module, each discharging module is provided with a metal net and a plurality of discharging needles which are positioned on the inner side of the metal net and arranged in an array manner, wherein the discharging needles are arranged in the metal net

The distance L between the needle tip of each discharge needle and the metal mesh is set to satisfy the condition that L is a L₁Wherein a is any constant in the range of 0.7 to 1.3, L₁In order to make the wind speed of the ion wind at the wind speed central point of the metal mesh reach the maximum wind speed V_maxThe distance between the needle point of the discharge needle and the metal mesh is equal to the distance between the needle point of the discharge needle and the metal mesh, and the wind speed central point of the metal mesh is a projection point of the needle point of the discharge needle on the metal mesh;

the housing includes:

a rear case for constituting a rear portion of the cabinet;

a front panel connected to a front side of the rear case to constitute a front of the cabinet; and

the two first side air ducts and the two second side air ducts are arranged in parallel in the front-rear direction, the first side air ducts and the second side air ducts are respectively positioned at two transverse ends between the rear shell and the front panel, and the first side air outlets and the second side air outlets are respectively formed at outer side ports of the two first side air ducts and the two second side air ducts;

the air duct of the fan assembly is provided with two lateral air duct outlets facing to the two transverse sides, and the transverse outer side ends of the first ion air generating device and the second ion air generating device are respectively provided with an air outlet facing to the transverse outer side; and is

The first side air duct at the front side and the second side air duct at the front side have inner side ports respectively connected with two lateral air duct outlets of the fan assembly, so that a first sealed air duct is formed among the second air inlet, the heat exchange device, the fan assembly, the first side air duct at the front side and the second side air duct at the front side; the inner side end ports of the first side air duct and the second side air duct on the rear side are respectively connected with the air outlets of the first ion wind generating device and the second ion wind generating device, so that a second sealed air duct which is completely separated from and independent of the first sealed air duct is formed among the first air inlet, the first ion wind generating device, the second ion wind generating device, the first side air duct on the rear side and the second side air duct on the rear side.

2. An indoor unit of an air conditioner according to claim 1,

the inner side of the top wall of the machine shell is provided with a partition wall, the partition wall vertically extends downwards from a position between the first air inlet and the second air inlet to a position between the first ion wind generating device and the heat exchange device and a position between the second ion wind generating device and the heat exchange device or extends to the front sides of air inlets of the first ion wind generating device and the second ion wind generating device, so that natural air flowing from the first air inlet to the first ion wind generating device and the second ion wind generating device is isolated from natural air flowing from the second air inlet to the heat exchange device.

3. An indoor unit of an air conditioner according to claim 1,

the rear shell is provided with a body extending vertically, and an upper edge part and a lower edge part which are bent and extended forwards from the upper end and the lower end of the body respectively; and is

The first air inlet is formed at the rear of the upper edge, and the second air inlet is formed at the front of the upper edge.

4. An indoor unit of an air conditioner according to claim 1, further comprising:

the first fan air guide channel and the second fan air guide channel respectively extend from two transverse sides of the fan assembly to the front parts of the first lateral air outlet and the second lateral air outlet in a bending mode so as to respectively guide air flowing to the first lateral air outlet and the second lateral air outlet through an air channel of the fan assembly; and

and the first ion wind guiding channel and the second ion wind guiding channel respectively extend to the rear parts of the first lateral air outlet and the second lateral air outlet in a bending way from the transverse outer ends of the first ion wind generating device and the second ion wind generating device so as to respectively guide the air flowing to the first lateral air outlet and the second lateral air outlet through the first ion wind generating device.

5. An indoor unit of an air conditioner according to claim 4,

the first fan air guide channel and the first ion air guide channel are both columnar, the first fan air guide channel extends along a first arc-shaped curve from inside to outside, and the first ion air guide channel extends along a second arc-shaped curve from inside to outside; and is

The second fan air guide channel and the first fan air guide channel are symmetrically arranged, and the second ion air guide channel and the first ion air guide channel are symmetrically arranged.

6. An indoor unit of an air conditioner according to claim 5,

the circle center of the circle with the first arc-shaped curve is positioned on the front side of the first arc-shaped curve, and the circle center of the circle with the second arc-shaped curve is positioned on the front side of the second arc-shaped curve; and is

The radius of the circle where the first circular arc-shaped curve is located is larger than that of the circle where the second circular arc-shaped curve is located.

7. An indoor unit of an air conditioner according to claim 1,

the inner side edge of a vertical bisection plane of the first lateral air outlet, which extends in the front-rear direction and is close to the indoor unit of the air conditioner, is more forward than the outer side edge of the first lateral air outlet, which is far away from the vertical bisection plane, so that the first lateral air outlet faces the front of the outer side of the machine shell; and is

The second lateral air outlet and the first lateral air outlet are symmetrically arranged.

8. An indoor unit of an air conditioner according to claim 1,

the distance R between the needle points of two adjacent discharge needles is set to satisfy the following conditions: r ═ aR₁Wherein R is₁For the wind speed to reach the maximum wind speed V_maxB is any constant within the range of 0.3-0.7.

9. An indoor unit of an air conditioner according to claim 1,

the first ion wind generating device and the second ion wind generating device respectively comprise a plurality of discharging modules which are sequentially arranged and connected in parallel or in series, and each discharging module is provided with a metal net and a plurality of discharging needles which are positioned on the inner side of the metal net and arranged in an array; and is

The discharge needles of two adjacent discharge modules are arranged in a straight-line opposite mode or in a staggered mode.

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