CN1178030C - Partition plate type air conditioner module - Google Patents

Abstract

The present invention relates to a partition type air conditioning module, which includes a screen, a heat transfer medium supply device, a heat transfer medium supply pipe, a heat transfer medium return pipe, a heat exchanger and a blower. The partition type air conditioning module is designed by integrating at least the heat exchanger and the blower into a vertically arranged screen to form a modular air conditioning module for personal use. Through the modular design, it can be flexibly combined and used to plan a personal work area in the office. By connecting it to the heat transfer medium supply device, it can provide the function of cooling or heating the room to meet the air conditioning function required by the personal work area. The partition type air conditioning module can be started and operated according to the actual needs of the personal work area and has the effect of saving energy.

Description

Partition type air conditioning module

technical field

The invention relates to an air-conditioning appliance, in particular to an air conditioner that integrates components such as a partition screen, a heat exchanger, a heat transfer medium delivery pipe, and a blower, which can be used as an indoor partition screen and meet the needs of individual work areas. Partition-type air-conditioning module for air-conditioning function.

Background technique

Most of the traditional refrigeration and air-conditioning equipment is designed to distribute the cold air to every corner of the room through the air outlets scattered in many places in the cold room. This design will have the following problems:

1. Regardless of the actual number of people in the cold room or the demand, the operation goal of the refrigeration and air-conditioning equipment is to make the cold room reach the preset temperature. If the actual number of people in the cold room is small, it will undoubtedly cause energy waste.

2. The outlet and return air adopt a large temperature difference, so the temperature of the ice water outlet and return water is low, or the evaporation temperature of the refrigerant is low, and the efficiency of the refrigeration equipment is relatively low.

3. The air-conditioning outlet installed on the ceiling, because more lamps are brought in, the radiant heat from the roof and walls will increase the unnecessary cooling load of the refrigeration and air-conditioning equipment, resulting in a waste of energy.

Contents of the invention

The object of the present invention is to propose a partition type air conditioning module composed of a screen, a heat transfer medium supply device, a heat transfer medium supply pipe, a heat transfer medium return air pipe, a heat exchanger and a blower, which can be flexibly combined It can be used alone, or it can be easily combined with several modules of the same type, combined with the wiring of the transmission and distribution pipelines of the heat transfer medium to form the partition screen of the office, and can avoid energy consumption. waste, thereby solving the existing problems of the prior art.

The technical solution adopted in the present invention is that it includes:

A screen, the interior of which is hollow, includes a frame on four sides and vertical surfaces respectively located on opposite sides of the screen, and the screen also has an air outlet and an air return port, the air outlet and the air return port pass through the air flow defined in the screen Road connected;

A heat transfer medium supply device;

a heat exchanger disposed in the air passage in the screen;

A heat transfer medium supply pipe, which connects the heat transfer medium supply device and the heat exchanger, and at least the other end of the heat transfer medium supply pipe can be connected with the heat transfer medium supply pipe of another partition type air-conditioning module connect;

A heat transfer medium suction pipe connects the heat transfer medium supply equipment and the heat exchanger, and at least the other end of the heat transfer medium suction return pipe can be connected to the heat transfer medium suction pipe of another partition type air-conditioning module Return pipe connection;

A blower is arranged in the air passage in the screen, and is interposed between the air return port and the heat exchanger.

The feature of the present invention is that it provides a clapboard air-conditioning module that can be flexibly combined and used to meet the air-conditioning functions required by individual working areas.

According to the air-conditioning needs of the actual number of users, it can provide the partition-type air-conditioning module with the air-conditioning function required by the personal work area, so as to avoid energy waste.

It can be used alone, or it can be easily combined with several partition air-conditioning modules of the same type, with the wiring of the transmission and distribution pipeline of the heat transfer medium to form an office partition screen, and it can also be used in combination with a desktop to become office partition furniture.

Using this clapboard air-conditioning module, the personal work area can be divided in the office, and then connected to the supply equipment of the heat transfer medium through the heat transfer medium delivery pipe, it can provide cooling room or air conditioning for the personal work area. It is the air-conditioning function of the heating room.

It can also be included that the air passage in the hollow inside of the screen is equipped with a filter screen, an air filter material (such as activated carbon) or an ozone air cleaner, etc. to purify the air, thereby filtering out larger particles such as dust. particles or remove some harmful substances in the air to achieve the effect of clean air.

Therefore, the present invention is particularly suitable for the division of personal work areas in the office, and the operation of each partition-type air-conditioning module is completely controlled by the user, and its air-conditioning function can just meet the individual's air-conditioning needs.

The clapboard-type air-conditioning module designed by the present invention is completely set up for the air-conditioning needs of individual working areas, and does not need to bear the additional cooling room load caused by buildings such as ceilings or walls, which can naturally reduce energy waste.

The clapboard-type air-conditioning module has the function of supplying fresh outside air, which can directly obtain the best ventilation effect in the personal working area.

Description of drawings

Fig. 1 is the construction diagram of the first embodiment of the clapboard type air conditioning module;

Fig. 2 is the exterior structure diagram of the clapboard type air conditioning module;

Fig. 3 is another embodiment structural diagram of partition type air conditioning module;

Figures 4 to 8 are cross-sectional views of the structure of the clapboard air-conditioning module, showing various embodiment structures of its internal structure;

Fig. 9 is another embodiment of the partition type air conditioning module, showing the structure of the detachable return air panel and the filter screen.

10A to 10B are cross-sectional views of the structure of the partition type air-conditioning module, showing the structure with wind guide vanes arranged at the air outlet;

Figures 11 to 12 are cross-sectional views of the structure of the partition type air-conditioning module, showing an example of a filter screen installed inside it;

13A to 13B show the structure in which the partition type air conditioning module is connected to the external air supply device.

Fig. 14 is a diagram of an application example of a partition type air-conditioning module, showing the situation as a partition screen in an office;

Fig. 15 is an appearance view of a partition-type air-conditioning module, showing two parallel-type partition-type air-conditioning modules of the same type.

16A to 16B are partial structural cross-sectional views of the partition air-conditioning module, showing the structure for connecting pipelines and closed pipelines;

Fig. 17 shows a cross-sectional structural view of two partition-type air-conditioning modules connected by a corner column at a turning point.

Figure 18 is a structural diagram of the connection between the partition type air conditioning module and the refrigerant supply equipment;

Fig. 19 is a construction diagram of an embodiment in which the partition type air conditioning module is connected to the ice water supply equipment;

Fig. 20 is a construction diagram of an embodiment in which the partition type air conditioning module is connected to the water supply equipment;

21A to 21C show several design diagrams for controlling the flow of refrigerant into the heat exchanger;

Figures 22 to 22C show several designs for controlling the flow of ice water or hot water into the heat exchanger;

Fig. 23 is a structural diagram of a clapboard air-conditioning module and an outlet air temperature controller;

Fig. 24 is a structural diagram of another embodiment of the partition type air conditioning module, showing the structure equipped with a human body sensor.

Detailed ways

Now further illustrate preferred specific embodiments of the present invention in conjunction with above-mentioned each accompanying drawing, as shown in Figure 1 and Figure 2, the clapboard type air conditioning module designed by the present invention, it comprises:

A screen 10, which has a frame 101 constituting the four sides of the screen 10 and vertical surfaces 11a, 11b respectively located on opposite sides of the screen 10, and is surrounded by the vertical surfaces 11a, 11b and the four-sided frame 101 to form a hollow screen 10. The screen 10 also has at least one air outlet 12 and an air return port 13, which communicate through the gas flow channel defined in the screen 10;

A heat transfer medium supply pipe 20, which is used to introduce the heat transfer medium (such as refrigerant, ice water or hot water) into the clapboard type air conditioning module, and the two ends of the supply pipe 20 are respectively an inlet end 201 and a series of The connection end 202, the entry end 201 is used to be connected with the supply source of the heat transfer medium, and the series connection end 202 can be connected with the entry end 201a of the supply pipe 20a of another same-type partition type air-conditioning module (as shown in Figure 15 ), so that another same-type bulkhead air-conditioning module can share the heat transfer medium from the same source;

A heat transfer medium suction pipe 21, which is used to lead the heat transfer medium back to the heat transfer medium supply source for recycling, and the two ends of the suction return pipe 21 are respectively an output end 211 and a recovery serial connection end 212 , the output end 211 is connected to the supply source of the heat transfer medium to lead the heat transfer medium that has completed the heat exchange function back to the supply end of the heat transfer medium, and the recovery serial connection end 212 can be connected to another same-type clapboard air conditioner The output end 211a of the suction pipe 21a of the module is connected (as shown in Figure 15 and Figure 16A), so that the heat transfer medium that completes the heat exchange function in another same-type partition air-conditioning module can be led back to the heat transfer medium together. source of supply;

A heat exchanger 30, which is arranged in the screen 10, its inlet port 301 is connected to the supply pipe 20, and the outlet port 302 is connected to the suction pipe 21, and the heat transfer medium supplied by the supply pipe 20 is used to flow through the heat exchanger 30 of the air is subjected to heat exchange treatment, and then flows out through the suction return pipe 21; and

A blower 40 is used to push the air from the air return port 13 through the aforementioned heat exchanger 30 , and then release it into the room from the air outlet 12 .

Please refer to Fig. 3 again, it is another preferred embodiment of the clapboard type air conditioning module of the present invention, it is based on the structure of Fig. Pan 31, and a condensed water discharge pipe 32, due to the dehumidification effect when providing the cooling room function, there will be water vapor condensed on the surface of the heat exchanger 30, and the collection through the water collecting pan 31 and the condensed water discharge pipe 32 The guide can discharge the condensed water.

The structure of the screen 10 is composed of a four-sided frame 101. The screen 10 has two vertical surfaces 11a and 11b respectively located on opposite sides, and can stand on the ground by means of a tripod 14 arranged at the bottom thereof (as shown in FIG. 2 ). Or stand upright on the ground through other fixing means such as nailing. Of course, if necessary, the screen 10 can also be fixed on the wall, or installed close to the wall.

The air outlet 12 and the return air outlet 13 are basically openings for connecting the inside and outside of the screen 10, and their setting positions can be implemented in various ways, for example:

The first feasible implementation mode is to arrange the air outlet 12 and the return air outlet 13 on the vertical surface 11a, 11b of the screen 10, and they can be located on the vertical surface 11a of the same side of the screen 10 (as shown in Figure 4), or These are vertical surfaces 11a, 11b (as shown in FIG. 5 ) respectively located on opposite sides.

In the second feasible implementation manner, the design of the air return port 13 is as shown above, and the air outlet 12 is arranged at the top edge of the screen 10, for example, at the top edge frame 101a of the screen 10 for upward discharge. Airflow (as shown in Figure 6).

The design of the air return port 13 of the third possible implementation is still the same as that of the first embodiment, and the air outlet 12 is arranged at three planes adjacent to each other at the top of the screen 10, that is, the two vertical surfaces of the screen 10 The upper edges of 11a, 11b, and the top edge frame 101a of the screen 10 allow the airflow to be discharged toward the direction of radiation (as shown in FIG. 7 ).

If the air-conditioning function of the cold room is mainly provided, the best position is that the air outlet 12 is on the top and the return air outlet 13 is on the bottom, so that the supplied air can be discharged into the room from top to bottom, because the cold air will naturally convect downward On the contrary, if the air-conditioning function of the warm room is the main function, the better configuration is designed with the air outlet 12 on the bottom and the return air outlet 13 on the top (as shown in Figure 8).

Another preferred embodiment of the air outlet 12 and the air return port 13 is to adopt a panel design for the air outlet 12 and the air return port 13, that is, to arrange the air outlet 12 and the air return port 13 on a flat plate, so that this The flat panel becomes a kind of air outlet panel 12a and the air return panel 13a installed on the vertical surface 11a of the screen 10, and the air return panel 13a respectively. Embedded means installed), in order to facilitate future cleaning (as shown in Figure 9).

At the air outlet 12 or the air return port 13, the wind guide vane 15 can also be installed, just like the design of the air outlet of a general air conditioner, it can be an automatic wind guide vane driven by a small motor 161 and a screw device 162 (as shown in Figure 10A and As shown in FIG. 10B ), it can also be a manual air guide vane that is completely adjusted by the user. This not only allows the user to determine the direction of the wind, but also avoids the discomfort caused by the airflow directly blowing the human body.

The air blower 40 is basically a fan, which can be a centrifugal fan or an axial fan. It uses the hollow inside of the screen 10 as an air flow channel to push the air from the air return port 13 through the hollow inside of the screen 10. The heat exchanger 30 is released into the room from the air outlet 12 after the heat exchange effect of the heat exchanger 30 . The preferred design also includes that the air passage in the hollow inside of the screen 10 is equipped with a filter screen 17, an air filter material (such as activated carbon) or an ozone air cleaner 18, etc. to purify the air (as shown in Figure 7 shown), so as to filter out larger particles such as dust or remove some harmful substances in the air to achieve the effect of clean air. Among them, the filter screen 17 is best (as shown in Figure 11) to be arranged at the inlet of the air (especially the position near the air return port 13) to ensure the cleanliness of the parts inside the screen 10. Of course, it can also be installed near the outlet. The position of the air outlet 12 (as shown in Figure 12), if it is used with the air outlet panel 12a or the return air panel 13a with a panel design, can be easily replaced after the air outlet panel 12a or the return air panel 13a is removed Or clean filter screen 17 and filter material.

The structure shown in Figure 13A and 13B is another kind of preferred embodiment of the clapboard type air-conditioning module designed by the present invention; The building arranges the external air delivery pipe 50 and necessary air supply devices, such as equipment such as blower 51 and air filter 52, and when it is necessary to take a breath or supply fresh external air, the fresh external air outside can be passed through the blower 51 and The outside air delivery pipe 50 is led to the outside air supply pipe 19 in the partition type air conditioning module, and after being pushed through the heat exchanger 30 inside the hollow of the screen 10, it is released into the room from the air outlet 12. Wherein the external air supply pipe 19 is configured at the bottom of the screen 10, and the width of its section should be as large as possible under the premise that the screen 10 can accommodate, so that a large amount of fresh external air passes through, and the aforementioned supply pipe 20 and suction The return pipe 21 can also be included in the air supply pipe 19 (as shown in FIG. 13B ), so as to make full use of the inner space of the screen 10 .

The clapboard type air-conditioning module designed by the present invention is mainly used to meet individual air-conditioning needs, so it is particularly suitable for use as an office partition partition (Partition) and to separate each person's work area. It can visually The actual space planning needs to flexibly divide many working areas for personal use through the combination of multiple partition air conditioning modules (as shown in Figure 14); in addition, the outlet of the air outlet 12 can also be viewed. If a desktop 60 is installed on any vertical surface 11a or 11b of the screen 10 according to the direction of the wind, it can become a desk for personal use. The user sits in front of the desktop 60 and can enjoy the advantages provided by this clapboard air-conditioning module. air conditioning function.

In terms of the modular design of the partition type air conditioning module, the present invention utilizes the means of pipeline sharing, so that when two partition type air conditioning modules are connected together, the supply pipe 20 used to transmit the heat transfer medium and The suction return pipe 21, the condensate discharge pipe 32 and the external air supply pipe 19 are connected in series (as shown in Figure 15), so that the two clapboard air-conditioning modules can supply heat transfer medium and fresh external air, and circulate Drain the condensate in the same way.

There are many ways to connect the supply pipe 20, the suction return pipe 21, and the condensate discharge pipe 32 of two partition air-conditioning modules to each other, for example, when two partition-type air-conditioning modules are connected to each other in the same plane ( As shown in Figure 16A), it can be connected together by a pipe connecting element 33 at its adjacent position; otherwise, if a partition type air conditioning module or a partition type air conditioning module at the end of the pipeline is used separately, It is also necessary to use a pipe closing element 35 (as shown in Figure 16B) to seal the end of the supply pipe 20, the suction pipe 21 or the condensed water discharge pipe 32. In a suitable position, a cover plate 36 that can be opened and closed must also be installed, so that the construction personnel can install the pipe connecting element 33 or the pipe closing element 35 after opening the cover plate 36 . As shown in Figure 17, when two partition air conditioner modules are connected to each other with a certain angle (such as when they are connected to each other at a corner), we can use one to connect the two partition air conditioners The corner post 102 of the module, and the elbow joint 37 installed in the corner post 102 . Connect the supply pipe 20, the suction pipe 21 and the condensate discharge pipe 32 respectively located in the two partition air-conditioning modules. Of course, where the bottom edge of the corner column 102 is aligned with the external air supply pipe 19 inside the two partition air-conditioning modules, a hollow channel 103 is reserved for connecting the external air supply inside the two partition air-conditioning modules. Tube 19.

The clapboard type air conditioning module of the present invention is not equipped with any heat transfer medium supply equipment, so it must be connected with the heat transfer medium supply equipment required by the air conditioner, and depending on the function of the air conditioner, the matching heat transfer medium The supply equipment may have the following several different implementation modes, which are described respectively as follows.

1. Use the refrigerant supply device 70; for example, when it is necessary to provide the air-conditioning function of cold room and dehumidification, the heat exchanger 30 of the clapboard air-conditioning module designed in the present invention can be used as a part of the evaporator of the refrigerant supply device 70 (as shown in the figure 13A), at this time, the refrigerant is compressed by the refrigerant compressor 71 to become a high-temperature refrigerant vapor that dissipates heat through the condenser, and then is supplied to the partition air-conditioning module through the distribution pipeline 81, and then enters through the refrigerant supply pipe 20 and an expansion device 38. The heat exchanger 30 can cool down the air flowing through the heat exchanger 30 by using the heat absorption effect of the refrigerant evaporated here, and the refrigerant after the action is led back to the refrigerant distribution pipeline 81 through the refrigerant suction return pipe 21 Return to the refrigerant supply equipment 70, and the water condensed on its surface can be discharged to the drainage equipment (such as the drainage pipeline 82 of the building) by using the catch pan 31 and the condensed water drain pipe 32 arranged below.

Conversely, if it is necessary to provide the function of warming the room, the heat exchanger 30 can be used as a part of the condenser of the refrigerant supply device 70 (as shown in Figure 18), and the heat release effect when the refrigerant is cooled here can be used. The air in this heat exchanger 30 is heated to provide the air-conditioning function of the heating room.

2. Use the ice water supply device 72; as shown in Figure 19, the ice water supplied by the ice water supply device 72 will be able to provide the cold energy required by the air conditioning function of the cold room.

3. Use the hot water supply device 73; as shown in Figure 20, the hot water supplied by the hot water supply device 73 can provide the heat energy required by the air-conditioning function of the heating room.

In principle, the aforementioned heat transfer medium supply equipment is installed outdoors, and it can deliver the heat transfer medium required by the air conditioner to each required compartment through the transmission pipe 81 (as shown in Figure 18) laid on the floor 80. Panel-type air-conditioning modules, therefore, the location of partition-type air-conditioning modules can be determined according to space planning to arrange the transmission and distribution pipelines 81 laid on the floor, and even form a transmission and distribution network.

In addition, we can also adopt the elevated wiring method, as shown in Figure 19 and Figure 20, the transmission and distribution pipeline 81 is arranged above the ceiling 83 and extended to a preset position, and then passes through a hollow wall or a hollow false The beams and columns 84 are connected to the nearest partition air-conditioning module to complete the arrangement of the transmission and distribution pipeline 81 of the heat transfer medium.

Due to the limited internal space of the screen 10, when installing the heat exchanger 30, a suitable type of heat exchanger 30 can be selected according to the needs of the operating capacity. As for the temperature control of the air outlet, the temperature sensing element 41 can be used to cooperate with the controller 42 (as shown in FIG. 23 ) to control the blower 40, the flow rate of the heat transfer medium or the speed of the refrigerant compressor 71 (such as an inverter compressor). The way to complete the control of the air outlet temperature. Taking the use of the refrigerant compressor 71 to provide the heat transfer medium to control the temperature of the cold room as an example, we can complete the control of the outlet air temperature by the following methods of controlling the flow rate into the heat exchanger 30, for example:

1. As shown in Figure 21A (the heat exchanger 30 at this time is used as an evaporator), we can set a temperature-sensitive expansion valve 38a in the supply pipe 20 to control the flow of the refrigerant. The temperature at the outlet port 302 is used to control the action of the thermosensitive expansion valve 38a, and then a shut-off valve 91 (such as a solenoid valve) installed at the front end of the thermosensitive expansion 38a is used to control whether the refrigerant enters or not.

2. In another embodiment (as shown in FIG. 21B ), a throttle valve 92 installed between the supply pipe 20 and the heat exchanger 30 is used to control the passage of the refrigerant through the expansion device 38 (such as a capillary tube) and then Flow into heat exchanger 30.

3. In another example shown in FIG. 21C, the refrigerant supplied by the supply pipe 20 is selectively supplied to several manifolds 30a1, 30a2, 30a3 constituting the heat exchanger 30a. Each manifold 30a1, In addition to the necessary expansion devices 38a, 38b, 38c, the inlets of 30a2, 30a3 are also equipped with shut-off valves 91a, 91b, 91c, respectively, to control whether the refrigerant can enter the manifolds 30a1, 30a2, 30a3.

If the clapboard type air-conditioning module uses the water-based heat transfer medium (ice water or hot water), its structure is shown in Figure 22A to Figure 22C, and it is completed by controlling the flow rate of the heat transfer medium into the heat exchanger 30. Outlet temperature control.

In the structure of the embodiment shown in FIG. 22A, a three-way flow control valve 93 is used to control the flow of the water system heat transfer medium into the heat exchanger 30. The three connection ends of the three-way flow control valve 93 are respectively connected to the supply The pipe 20, the suction pipe 21, and the inlet port 301 of the heat exchanger 30, as long as part of the water system heat transfer medium from the supply pipe 20 is directly guided to the suction pipe 21 by using the three-way flow control valve 93, the water system heat transfer can be reduced. The flow rate of the medium entering the heat exchanger 30 , otherwise, the flow rate of the water-based heat transfer medium entering the heat exchanger 30 can be increased.

In the structure of the embodiment shown in FIG. 22B , a two-way flow control valve 94 is used to control the flow of the water system heat transfer medium into the heat exchanger 30 .

As for the structure of the embodiment shown in FIG. 22C, the water-based heat transfer medium supplied by the supply pipe 20 is selectively supplied to several manifolds 30a1, 30a2, 30a3 constituting the heat exchanger 30a. Each manifold 30a1, A shut-off valve 91a, 91b, 91c is respectively installed at the inlets of 30a2, 30a3 to control whether the water system heat transfer medium can enter the manifolds 30a1, 30a2, 30a3 respectively.

In addition, the purpose of controlling the temperature of the air outlet can also be achieved by controlling the air volume of the air outlet 12 , such as controlling the air volume of the blower 40 or changing the size of the air outlet 12 . In a preferred embodiment, a controller 42 (as shown in FIG. 23 ) is also provided on the vertical surface of the clapboard air-conditioning module disclosed in the present invention. This controller 42 has at least:

A start button 421 for starting the operation of the clapboard air-conditioning module;

An air volume control button 422, used to control the air volume of the blower 40;

A temperature control circuit (not shown in the figure), which can set the required air outlet temperature, and control the speed of the blower 40 or the refrigerant compressor 71 according to the return air temperature measured by the temperature sensing element 41, or As shown in FIG. 21A to FIG. 21C and FIG. 22A to FIG. 22C , the temperature of the outlet air is controlled by controlling the flow rate of the heat transfer medium.

Of course, if the clapboard type air conditioner module is also equipped with components such as ozone air cleaner 18 or automatic wind guide vane 15, it is also necessary to add necessary control switches to the controller 42, and even a temperature display 43 to provide comprehensive operating functions .

Finally, please refer to Figure 24. The embodiment disclosed in this figure is a clapboard air-conditioning module that can be started automatically, mainly because a human body sensor 44 (Occupied Sensor) is installed in the clapboard air-conditioning module for Detect whether the working area in the air outlet direction of the partition type air conditioning module is being used, and further decide whether to activate the partition type air conditioning module to provide the air conditioning mechanism required by this area, otherwise when no one or personnel leave this area When the time is up, the operation of the clapboard type air-conditioning module can be stopped, so as to achieve the purpose of timely application and energy saving.

Claims (18)

1. A clapboard air-conditioning module, characterized in that it includes: A screen, the interior of which is hollow, includes a frame on four sides and vertical surfaces respectively located on opposite sides of the screen, and the screen also has an air outlet and an air return port, the air outlet and the air return port pass through the air flow defined in the screen Road connected; A heat transfer medium supply device; a heat exchanger disposed in the air passage in the screen; A heat transfer medium supply pipe, which connects the heat transfer medium supply device and the heat exchanger, and at least the other end of the heat transfer medium supply pipe can be connected with the heat transfer medium supply pipe of another partition type air-conditioning module connect; A heat transfer medium suction pipe connects the heat transfer medium supply equipment and the heat exchanger, and at least the other end of the heat transfer medium suction return pipe can be connected to the heat transfer medium suction pipe of another partition type air-conditioning module Return pipe connection; A blower is arranged in the air passage in the screen, and is interposed between the air return port and the heat exchanger. 2. The clapboard type air-conditioning module as claimed in claim 1, characterized in that said heat transfer medium supply equipment includes a refrigerant supply equipment of a refrigerant compressor, a condenser and an expansion device, wherein the heat exchange The device is connected to the supply pipe through the expansion device, and is used as an evaporator of the refrigerant supply equipment. 3. The partition type air-conditioning module as claimed in claim 1, characterized in that said heat transfer medium supply device is an ice water supply device. 4. The clapboard type air-conditioning module as claimed in claim 2 or 3, characterized in that it also includes a water collecting pan and a condensate drain pipe, the water collecting pan is arranged under the heat exchanger, and the water collecting pan and a condensate drain pipe Condensate drain connection. 5. The clapboard-type air-conditioning module as claimed in claim 2 or 3, characterized in that the air outlet and the return air outlet are arranged on the vertical surface of one side of the screen, and the air outlet is on the top and The return air vent is down. 6. The clapboard-type air-conditioning module as claimed in claim 2 or 3, characterized in that the air outlet and the return air outlet are respectively set on the vertical surfaces of different sides of the screen, and the air outlet is on the top and The return air vent is down. 7. The clapboard type air conditioning module according to claim 1, characterized in that the air outlet and the return air outlet are arranged on a flat plate, and the flat plate is respectively a kind of air outlet that can be installed on the vertical surface. panel and return panel. 8. The panel-type air-conditioning module as claimed in claim 1, further comprising a guide vane, which is arranged at the air outlet and the air return. 9. The partition type air-conditioning module as claimed in claim 1, further comprising a filter, which is arranged in the air flow channel inside the screen. 10. The partition type air conditioning module as claimed in claim 1, further comprising an ozone air cleaner provided in the air passage in the screen. 11. The panel-type air-conditioning module as claimed in claim 1, characterized in that the screen also has a tabletop, and the tabletop is located in the middle of the screen. 12. The partition type air-conditioning module according to claim 1, characterized in that said heat transfer medium supply equipment includes a refrigerant supply equipment of a refrigerant compressor, an evaporator and an expansion device, wherein the heat exchange The condenser is a condenser used as a refrigerant supply device. 13. The partition type air-conditioning module as claimed in claim 1, characterized in that said heat medium supply device is a hot water supply device. 14. The clapboard type air conditioning module according to claim 12 or 13, characterized in that the air outlet and the return air outlet are located on the same side of the vertical surface of the screen, and the air outlet is below and the The return air vent is on the top. 15. The clapboard air-conditioning module according to claim 12 or 13, characterized in that the air outlet and the return air outlet are respectively arranged on the vertical surfaces of different sides of the screen, and the air outlet is below and the The return air vent is on the top. 16. The clapboard-type air-conditioning module as claimed in claim 2 or 12, characterized in that the refrigerant compressor is a variable-frequency compressor, and the air-conditioning module also includes: A temperature sensing element, which detects the return air temperature of the air return port, thereby changing the temperature of the outlet air. 17. The clapboard type air conditioning module according to claim 2 or 12, characterized in that the inlet end of the heat exchanger is equipped with a temperature-sensitive expansion valve to adjust the flow rate of the refrigerant entering the heat exchanger . 18. The clapboard type air conditioning module as claimed in claim 1, characterized in that it also comprises: an external air supply pipe arranged inside the frame; an outside air delivery pipe provided in the building, one end of which is connected to the outside air supply pipe; and A blower fan and an air filter arranged outside, the blower fan and the air filter are connected, and the blower fan and the air filter are connected with the external air delivery pipe.

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