TWM481373U - Temperature adjustment module structure - Google Patents

Description

Temperature control module structure

This creation department relates to a temperature regulation module structure for cold storage or heat storage, especially a temperature regulation module structure.

Generally, in the summer or during high temperature indoors, the air conditioner or the cold fan that discharges the cold air is used to lower the temperature, and in the winter or the lower temperature room, the heater or the hot fan that discharges the hot air is also used. To increase the temperature. However, regardless of the airflow device such as cold air or warm air, most of the starting time is at the peak of power consumption.

Today, a temperature control device has been developed. The temperature control device is provided with an energy storage material. The energy storage material can store energy in advance during the low peak period of electricity consumption, and the air flow device is turned on during the peak period of power consumption to match the air flow device and the energy storage material. The use of the temperature control device has the effect of blowing cold air or hot air, and by adjusting the amount of energy storage material, the strength of the cold or the heat is determined to achieve the effect of temperature regulation.

The temperature regulating device is configured corresponding to the airflow device, so that the airflow generated by the airflow device contacts the energy storage material, and the cooled or heated airflow flows into the indoor environment, thereby increasing or decreasing the temperature of the indoor environment. Therefore, how to make the temperature regulating device increase or decrease the amount of energy storage materials according to the demand and make the indoor temperature reach the preset value is one of the functions that the temperature regulating device needs to have.

In view of this, the special research and the use of the theory, that is, the improvement of the creator The goal.

One of the purposes of the present invention is to provide a temperature regulation module structure, which can increase or decrease the number in an assembled manner by using an energy storage component, thereby achieving the effect of conveniently adjusting the number of energy storage components.

In order to achieve the above objective, the present invention provides a temperature control module structure for an air flow device. The temperature control module structure includes: a body having an accommodation space and a first part for connecting the accommodation space a tuyere and a second tuyere, wherein the airflow device is disposed corresponding to the first tuyere; and at least one of the accumulator assemblies as described above, the fixture is detachably coupled to the body, and the accumulator component is placed The accommodation space.

This creation also has the following effects:

First, the heat storage energy of the energy storage material is large, so that the energy storage component continuously cools or heats up the flowing airflow, so that the energy storage component can pre-store energy during the low peak period of electricity consumption, and then use it during the peak hours of power consumption, and further Reaching peak shifting and filling valleys reduces the peak electricity consumption, improves energy efficiency, and saves electricity costs.

Second, the number of the arrangement of the energy storage components may be increased or decreased in a group manner, so that the temperature adjustment capability of the temperature regulation module structure has a weak, medium, and strong effect, and the temperature of the flowing airflow is also weak and medium. Strong effect.

Third, the energy storage component can be quickly assembled or disassembled to the hanger to facilitate replacement of the energy storage component.

Fourth, the number of energy storage components of each energy storage component is plural, and each energy storage component is sequentially Cascaded and stacked on the hanging member, the energy storage components can also be arranged side by side, so that the single energy storage component can adjust the number of energy storage components according to the situation, so that the single energy storage component has a weak, medium and strong temperature regulation effect, or The group of energy storage components can adjust the number of juxtapositions according to the situation, so that the temperature adjustment module structure has weak, medium and strong temperature regulation effects.

100‧‧‧Airflow device

101‧‧‧ airflow

10‧‧‧ thermostat module structure

1‧‧‧ Ontology

11‧‧‧ accommodating space

12‧‧‧ first air outlet

13‧‧‧second air outlet

14‧‧‧ top

141‧‧ ‧ empty slot

15‧‧‧Hanging Department

16‧‧‧ Cover

161‧‧‧ bottom

17‧‧‧ Third air outlet

2‧‧‧ Energy storage components

20‧‧‧Fixed parts

21‧‧‧ hanging pieces

211‧‧‧Hook

212‧‧‧hanging rod

213‧‧‧ lanyard

214‧‧‧U type lanyard

215‧‧‧ net bag

22‧‧‧ Energy storage components

221‧‧‧through holes

222‧‧‧ring groove

3‧‧‧Frame

The first figure is a perspective assembled view of the first embodiment of the present energy storage assembly.

The second figure is an exploded perspective view of the first embodiment of the present temperature control module structure.

The third figure is a three-dimensional combination diagram of the first embodiment of the present temperature control module structure.

The fourth figure is a schematic cross-sectional view of the first embodiment of the present temperature control module structure.

The fifth figure is another schematic cross-sectional view of the first embodiment of the present temperature control module structure.

The sixth figure is another schematic cross-sectional view of the first embodiment of the present temperature control module structure.

The seventh figure is a schematic cross-sectional view of the second embodiment of the structure of the temperature control module.

The eighth figure is a schematic view showing the state of use of the second embodiment of the present energy storage component.

The ninth drawing is a perspective assembled view of the third embodiment of the present energy storage assembly.

The tenth figure is a three-dimensional combination diagram of the fourth embodiment of the present energy storage assembly.

The eleventh figure is a three-dimensional combination diagram of the fifth embodiment of the present energy storage assembly.

Figure 12 is a perspective assembled view of a sixth embodiment of the present energy storage assembly.

Figure 13 is a schematic view showing the state of use of the sixth embodiment of the present energy storage assembly.

Figure 14 is a schematic view showing another use state of the sixth embodiment of the present energy storage assembly.

The detailed description and technical content of the present invention will be described below in conjunction with the drawings, but the drawings are for illustrative purposes only and are not intended to limit the present invention.

Please refer to the first to sixth figures. The present invention provides a first embodiment of a temperature regulation module structure for an airflow device 100. The airflow device 100 can generate an airflow 101. The temperature regulation module structure 10 is mainly A body 1 and one or a plurality of energy storage components 2 are included.

The airflow device 100 is exemplified by a fan, and the fan can be a fan or a suction fan.

As shown in the second to fifth figures, the main body 1 has a receiving space 11 and a first air outlet 12 and a second air outlet 13 that communicate with the receiving space 11. The airflow device 100 is disposed corresponding to the first air outlet 12. The first tuyere 12 and the second tuyere 13 are respectively formed at opposite ends of the body 1.

In addition, the body 1 of the present embodiment is a frame 3, but is not limited thereto. The frame 3 has a top portion 14 disposed above the accommodating space 11, and the top portion 14 has one or a plurality of hanging portions 15.

Further, the frame 3 further includes one or a plurality of cover plates 16 , and the top portion 14 is provided with one or a plurality of transparent slots 141 that communicate with the accommodating space 11 . The cover plates 16 are respectively covered by the respective vacant slots 141 and are respectively hanged. The portion 15 is formed at the bottom 161 of each cover plate 16.

In addition, the airflow device 100 can be separated from the frame 3, and the airflow device 100 can also be fixed in the frame 3, so that the frame 3 can be a fixed frame or a movable frame relative to the airflow device 100; wherein the embodiment discloses the airflow device 100 is fixed in the frame 3, and the frame 3 is provided with a third tuyere 17 corresponding to the airflow device 100, but is not limited thereto, and can be adjusted according to actual conditions.

As shown in the first figure, the energy storage assembly 2 includes a fixing member 20 and one or more energy storage elements. 22, the energy storage component 22 is detachably connected to the fixing component 20, and the fixing component 20 is detachably connected to the frame 3, and the energy storage component 2 is accommodated in the accommodating space 11, and the fixing component 20 is optimally implemented. For example, a hanging member 21 is not limited thereto, and the hanging member 21 can be attached to the hanging portion 15 in a stacking manner.

The accumulator element 22 is provided with a cold storage or heat storage material; in addition, the energy storage element 22 can be a spherical block, a circular block, a cylindrical block, a rectangular block, a triangular block, and a circular ring block. A geometric block such as a rectangular ring block or a triangular ring block, the appearance of the energy storage element 22 is not limited by this embodiment.

Furthermore, the end of the hanging member 21 has a hook portion 211, and the hook portion 211 can be hung corresponding to the hanging portion 15, and the hanging member 21 can be assembled or detached from the hanging portion 15 through the hook portion 211. The shape of the hook portion 211 is not limited to the hook shape, and the appearance can be adjusted according to the needs.

Moreover, the hanging member 21 is a hanging rod 212, and the energy storage element 22 is provided with a permanent through hole 221, and the energy storage element 22 is sleeved through the through hole 221 and fixed to the hanging rod 212, even if the energy storage element 22 can be assembled or disassembled. Pendant 21.

The number of the hanging portion 15 and the accumulator assembly 2 is plural, and each of the hanging portions 15 is arranged side by side in the direction of the second tuyere 13 toward the second tuyere 13 at the top portion 14 so that the energy storage units 2 are arranged in parallel at intervals. Arranged in the accommodating space 11.

As described in detail below, the number of the hanging portion 15, the accumulator assembly 2, the through-groove 141, and the cover plate 16 is plural, and the respective through-grooves 141 are arranged side by side at intervals from the first tuyere 12 toward the second tuyere 13 at the top. 14. The energy storage units 2 are arranged side by side in the accommodating space 11 at intervals.

The combination of the present energy storage components 2, as shown in the first figure, utilizes the energy storage element 22 It can be connected to the fixing member 20 in a stackable manner. Thereby, the energy storage assembly 2 can be increased or decreased in a group manner, thereby facilitating the adjustment of the number of the plurality of energy storage elements at a time.

The combination of the present temperature control module structure 10, as shown in the second to fifth figures, is that the body 1 has an accommodation space 11 and is provided with a first tuyere 12 and a second tuyere 13 that communicate with the accommodation space 11. The device 100 is disposed corresponding to the first air outlet 12; the energy storage component 2 is received in the accommodating space 11, and the energy storage component 2 includes a fixing component 20 and an energy storage component 22, and the energy storage component 22 is detachably connected to the fixing component 20, and is fixed. The member 20 can be detachably connected to the body 1. Thereby, the energy storage component 2 can be increased or decreased in a group manner, thereby achieving the effect of the temperature adjustment module structure 10 having the convenience of adjusting the number of the energy storage components 22.

The use state of the temperature control module structure 10 and the energy storage component 2, as shown in the fourth to sixth figures, regardless of whether the fan can be a fan or a suction fan, the airflow device 100 generates an airflow 101 when starting, so that the airflow 101 The first air outlet 12, the accommodating space 11 and the second air vent 13 are sequentially flowed sequentially or in reverse; first, the energy storage element 22 is pre-cooled or heated during a low-peak period (such as at night), and then The energy storage element 22 is placed in the accommodating space 21, so that the energy storage element 22 continues to cool or raise the temperature of the airflow 101 flowing therethrough. The energy storage component 22 pre-stores energy during the low-peak period (such as nighttime) during use, and is used in the peak hours of the power consumption, thereby achieving the effect of shifting peaks and valleys to reduce peak power consumption, improving energy use efficiency, and saving electricity costs.

In addition, as shown in the sixth figure, the number of the hanging portion 15, the energy storage unit 2, the through-hole 141, and the cover 16 is plural, and each of the transparent grooves 141 is spaced from the first tuyere 12 toward the second tuyere 13 The storage unit 2 is disposed in the bottom portion 161 of each of the cover plates 16 , and the energy storage assembly 2 is received in the accommodating space 11 for accumulating energy. The component 22 is detachably connected to the hanging member 21, and the hanging member 21 is detachably attached to the hanging portion 15 so that the energy storage assemblies 2 are arranged side by side at intervals. The accommodation space 11 is provided. Thereby, each group of energy storage components 2 are arranged correspondingly in front and rear and arranged side by side, so that the number of arrays of the energy storage components 2 can be increased or decreased in a group manner as the case may be, so that the temperature regulation capability of the temperature regulation module structure 10 is weak and medium. The strong effect, and then the temperature of the outgoing gas stream 101 also has a weak, medium and strong effect.

Moreover, the energy storage component 2 is hung on the cover plate 16 to facilitate the replacement of the energy storage component 2, that is, when the energy storage component 22 returns to normal temperature, only the energy storage component 2 is extracted to replace the energy storage component 22, so that the temperature adjustment can be performed. The module structure 10 quickly restores the unit's ability to continuously blow cold or hot air.

In addition, the end of the hanging member 21 has a hook portion 211, and the hook portion 211 can be hung corresponding to the hanging portion 15, even if the hanging member 21 can be quickly assembled or disassembled to the hanging portion 15 to facilitate the use of the energy storage assembly 2.

Moreover, the hanging member 21 is a hanging rod 212, and the energy storage element 22 is provided with a through hole 221, and the energy storage element 22 is sleeved through the through hole 221 and fixed to the hanging rod 212, even if the energy storage element 22 can be quickly assembled or disassembled. Pendant 21 to facilitate replacement of energy storage element 22.

Please refer to the seventh embodiment, which is the second embodiment of the temperature control module structure. The second embodiment of the temperature regulation module structure 10 is substantially the same as the first embodiment, but the second embodiment of the temperature regulation module structure 10 The difference from the first embodiment is that the air flow device 100 is fixed to the rear of the frame 3.

However, the present airflow device 100 can be fixed to the front or the rear of the frame 3, and the position of the airflow device 100 does not affect the function and efficacy of the temperature regulating module structure 10 and the energy storage component 2.

Referring to the eighth to ninth embodiments, the second to third embodiments of the present energy storage assembly, the second to third embodiments of the energy storage assembly 2 are substantially the same as the first embodiment, but the energy storage assembly 2 is second to third. The embodiment differs from the first embodiment in that the shape of the energy storage element 22 is not with.

However, the energy storage element 22 can be a spherical block, a circular block, a cylindrical block, a rectangular block, a triangular block, a circular ring block, a rectangular ring block or a triangular ring block. The block, and thus the shape of the energy storage element 22, is not limited by the above embodiments.

In addition, the number of the energy storage elements 22 of each of the energy storage components 2 is plural, and the energy storage elements 22 are sequentially connected in series and stacked on the hanger 21, so that the single energy storage component 2 can adjust the energy storage component 22 as appropriate. The quantity allows the single energy storage component 2 to have a weak, medium, and strong temperature regulation effect.

Referring to the tenth embodiment, in the fourth embodiment of the present invention, the fourth embodiment of the energy storage assembly 2 is substantially the same as the first embodiment, but the fourth embodiment of the energy storage assembly 2 is different from the first embodiment. The hanging member 21 of the fourth embodiment of the energy storage assembly 2 is a lanyard 213.

Further, the energy storage element 22 is provided with a uniform through hole 221, and the energy storage element 22 is sleeved on the lanyard 213 through the through hole 221, so that the energy storage element 22 can be quickly assembled or disassembled to the hanging member 21 to facilitate the energy storage element 22 . Replace it.

Referring to FIG. 11 , a fifth embodiment of the present energy storage assembly, the fifth embodiment of the energy storage assembly 2 is substantially the same as the first embodiment, but the fifth embodiment of the energy storage assembly 2 and the first embodiment The difference is that the hanging member 21 of the fifth embodiment of the energy storage assembly 2 is a U-shaped lanyard 214.

Further, as described below, the outer peripheral edge of the energy storage element 22 defines a ring-shaped groove 222, and the U-shaped lanyard 213 is fitted to the annular groove 222, so that the energy storage element 22 is positioned on the U-shaped lanyard 214 to make the energy storage element. 22 can be quickly assembled or disassembled to the hanger 21 to facilitate replacement of the energy storage element 22.

Referring to the twelfth to fourteenth drawings, a sixth embodiment of the present energy storage assembly, the sixth embodiment of the energy storage assembly 2 is substantially the same as the first embodiment, but the sixth embodiment and the first embodiment of the energy storage assembly 2 An embodiment differs in that the hanger 21 of the sixth embodiment of the energy storage assembly 2 is a mesh pocket 215.

Further, as follows, one or more of the energy storage elements 22 can be received in the mesh bag 215, so that the energy storage component 22 can be quickly assembled or disassembled to the hanger 21 to facilitate replacement of the energy storage component 22.

In addition, referring to the sixth figure, the frame 3 of the sixth embodiment is not provided with the through-groove 141 and the cover plate 16. Since the frame 3 of the present invention is not limited by the above embodiments, it can be adjusted according to actual conditions. Only the frame 3 has the hanging portion 15 and the hanging member 21 can be hung.

In summary, the structure of the temperature control module of this creation can achieve the intended purpose of use, and solve the lack of knowledge, and has industrial utilization, novelty and progress, fully comply with the requirements of new patent applications, and converts patents. If the law is filed, please check and grant the patent in this case to protect the rights of the creator.

100‧‧‧Airflow device

10‧‧‧ thermostat module structure

1‧‧‧ Ontology

13‧‧‧second air outlet

14‧‧‧ top

141‧‧ ‧ empty slot

16‧‧‧ Cover

17‧‧‧ Third air outlet

2‧‧‧ Energy storage components

21‧‧‧ hanging pieces

22‧‧‧ Energy storage components

3‧‧‧Frame

Claims (15)

A tempering module structure for an airflow device, the tempering module structure comprising: a body having an accommodating space and a first air outlet and a second air vent connecting the accommodating space, The airflow device is disposed corresponding to the first air outlet; and the at least one energy storage component is disposed in the accommodating space, the energy storage component includes: a fixing component; and at least one energy storage component, the energy storage component is detachably connected The fixing member is detachably connected to the body. The tempering module structure of claim 1, wherein the fixing member is a hanging member, and the hanging member has a hook portion at the end, and the hanging member is hung on the body through the hook portion. The tempering module structure of claim 2, wherein the number of energy storage components of each of the energy storage components is plural, and the energy storage components are sequentially connected in series and stacked on the hanger. The tempering module structure of claim 2, wherein the hanging member is a hanging rod, the energy storage element is provided with a continuous perforation, and the energy storage element is sleeved to the hanging rod through the through hole. The tempering module structure of claim 2, wherein the hanging member is a lanyard, the energy storage element is provided with a continuous perforation, and the energy storage element is sleeved to the lanyard through the through hole. The tempering module structure of claim 2, wherein the hanging member is a U-shaped lanyard, and an annular groove is formed on an outer circumference of the energy storage component, and the U-shaped lanyard is matched with the annular groove. The energy storage element is positioned on the U-shaped lanyard. The temperature regulation module structure of claim 2, wherein the hanging component is a mesh bag, and the energy storage component is received in the mesh bag. The temperature regulation module structure according to claim 1, wherein the energy storage component is a spherical block, a circular block, a cylindrical block, a rectangular block, a triangular block, a circular ring block, and a moment. Type ring block or a triangle ring block. The tempering module structure of claim 2, wherein the body is a frame, the frame has at least one hanging portion, and the hanging member is detachably mounted on the hanging portion through the hook portion. The temperature regulation module structure of claim 9, wherein the frame has a top portion disposed above the accommodating space, and the hang portion corresponds to the top portion. The temperature control module structure of claim 10, wherein the number of the hanging portion and the energy storage component is plural, and the hanging portions are arranged side by side from the first air outlet toward the second air outlet in a side by side manner. And arranging the energy storage components in the accommodating space in a side by side manner. The tempering module structure of claim 10, wherein the frame further comprises at least one cover plate, and the top portion is provided with at least one permeable slot that communicates with the accommodating space, the cover plate corresponding to the venting cover, And the hanging portion is formed at the bottom of the cover. The tempering module structure of claim 12, wherein the number of the hanging portion, the energy storage assembly, the vacant space, and the cover plate is plural, and the permeable slots are oriented from the first air outlet toward the second air vent The spacers are arranged side by side at the top, and the energy storage components are arranged side by side in the accommodating space. The temperature regulation module structure of claim 9, wherein the air flow device is fixed in the frame, and the frame is provided with a third air outlet corresponding to the air flow device configuration. The tempering module structure of claim 1, wherein the first tuyere and the second tuyere are respectively formed at opposite ends of the body.