CN111854164A - Temperature control cabin with temperature compensation function and gas heat exchange equipment applying same - Google Patents

Abstract

The invention discloses a temperature control cabin with a temperature compensation function and gas heat exchange equipment using the same, wherein the temperature control cabin comprises an upper cover shell, a flow guide pipe, a temperature compensation assembly, a lower cover shell assembly and a control assembly, wherein the side wall of the lower cover shell assembly is provided with a water inlet; the upper cover shell is connected with the lower cover shell assembly to form a water storage cavity, the flow guide pipe is arranged in the water storage cavity, the lower end of the flow guide pipe is hermetically connected with the bottom of the lower cover shell assembly, and the temperature compensation assembly is arranged on the outer wall of the lower cover shell assembly; the control assembly adjusts the electrode direction of the temperature compensation assembly according to the refrigeration or heating requirement of a user and is used for performing temperature compensation on water in the water storage cavity. By adopting the temperature control cabin, hot water or cold water flowing into the temperature control cabin can be subjected to thermal compensation or cold compensation, so that the temperature of outlet water is constant within a certain temperature range, and the problem of sudden cooling and sudden heating is effectively solved, thereby meeting the bathing scene requirements of users and improving the use comfort of the users.

Description

Temperature control cabin with temperature compensation function and gas heat exchange equipment applying same

Technical Field

The invention belongs to the technical field of gas heat exchange equipment, and particularly relates to a temperature control cabin with a temperature compensation function and gas heat exchange equipment applying the temperature control cabin.

Background

Gas heater, gas heating stove or other gas indirect heating equipment (except circulation system model) on the market at present, the in-process that uses is closed the water valve and is restarted the back and need just can reach the bath temperature before a period of time to influenced user's bathing comfort level, the leading cause who produces above-mentioned problem lies in: 1) after the water valve is closed, the residual heat of the heat exchanger continues to heat the stored water in the machine, so that the temperature of the stored water is higher than the set temperature, and the high-temperature stored water flows out firstly after the water valve is boiled again; 2) a certain amount of cold water needs to flow out in the process of re-opening the water valve until the inlet water temperature reaches a set value.

In addition, whether the gas heat exchange equipment (such as a gas water heater) is constant in temperature is always a key factor for measuring the excellent performance of the water heater, and the constant temperature performance is the most direct experience for the use comfort of users. At present, the constant temperature performance is mainly ensured by two aspects; firstly, a constant temperature algorithm of the water heater is used for matching an optimal heat load interval by calculating the temperature difference of inlet water and outlet water and monitoring the water flow, so that the outlet water temperature is consistent with the set temperature expected by a user; and secondly, a bypass pipeline is arranged at the water outlet end of the heat exchanger, and the temperature requirement is met through compensation. However, the constant temperature algorithm only adjusts the load by controlling in the using process of the user, and the constant temperature algorithm has an unobvious effect on the control of frequent water cut-off and temperature fluctuation of boiled water in the using process of the user, and even has a great influence on the using comfort of the user within a period of time of water cut-off and boiling; the bypass pipeline compensation is to compensate the temperature difference between cold water and hot water, but the problems of overlarge fluctuation of water cut-off temperature, easy generation of sudden cold and sudden heat and easy occurrence of frost cracking in a low-temperature environment cannot be well solved.

Disclosure of Invention

In view of the above, the present invention provides a temperature control cabin with a temperature compensation function, which solves the problems that the temperature of water flowing into the temperature control cabin cannot be compensated, sudden cooling and sudden heating are easily generated, and frost cracking easily occurs in a low temperature environment in the conventional temperature control cabin.

The invention also aims to provide the gas heat exchange equipment applying the temperature control cabin.

In order to achieve the purpose, the technical scheme of the invention is realized as follows: the temperature compensation device comprises an upper cover shell, a flow guide pipe, a temperature compensation component, a lower cover shell component with a water inlet formed in the side wall and a control component; the upper cover shell is connected with the lower cover shell assembly to form a water storage cavity, the flow guide pipe is arranged in the water storage cavity, the lower end of the flow guide pipe is connected with the bottom of the lower cover shell assembly in a sealing mode, the temperature compensation assembly is arranged on the outer wall of the lower cover shell assembly, and the control assembly is electrically connected with the temperature compensation assembly and used for compensating the temperature of water in the water storage cavity.

Preferably, this temperature control cabin still includes the spacer that can take place elastic deformation, the diaphragm sets up between upper cover casing and lower cover casing subassembly, form the gas storage cavity between upper cover casing and the diaphragm, form the water storage cavity between lower cover casing subassembly and the diaphragm, the honeycomb duct sets up in the water storage cavity.

Preferably, the lower cover shell assembly comprises a lower cover shell and a barrel, the barrel is arranged above the lower cover shell, the barrel and the diaphragm are sequentially connected to form a water storage cavity, and the water inlet and the temperature compensation assembly are arranged on the outer wall of the barrel.

Preferably, the temperature compensation assembly comprises a refrigeration and heating piece, a heat transfer pad, a first fixing support and a heat dissipation unit, wherein the heat transfer pad, the refrigeration and heating piece and the heat dissipation unit are sequentially and fixedly arranged on the outer side wall of the barrel from inside to outside through the first fixing support.

Preferably, the heat dissipation unit includes a heat dissipation plate and a heat dissipation pin, and the heat dissipation pin is disposed on a side of the heat dissipation plate away from the cooling and heating sheet.

Preferably, the temperature control chamber further comprises a pressure relief assembly, and the pressure relief assembly is arranged on the upper cover shell and used for performing safe pressure relief when the pressure in the air storage cavity reaches overpressure.

Preferably, the cooling and heating plate includes a first insulating base, a second insulating base, a first conductor layer, a second conductor layer, a P-type semiconductor block, and an N-type semiconductor block, the first insulating base and the second insulating base are disposed in parallel to each other, the first conductor layer and the second conductor layer are disposed inside the first insulating base and the second insulating base in an opposing manner, the P-type semiconductor block and the N-type semiconductor block are disposed between the first conductor layer and the second conductor layer and abut against each other, and a gap is disposed between the second conductor layers.

Preferably, a water inlet joint is arranged at the position of the water inlet on the cylinder, a water outlet is further arranged at the position, corresponding to the lower end of the flow guide pipe, on the lower cover shell, and a water outlet joint connected with the flow guide pipe is arranged at the position of the water outlet.

Preferably, the water inlet joint is in an L shape.

Preferably, the edge of the upper cover shell extends outwards to form a flanged flange, the upper edge of the cylinder extends outwards to form a flange, the edge of the diaphragm abuts against the flange, and the flanged flange covers the edge of the buckled diaphragm and the flange.

Preferably, the upper cover shell and the lower cover shell are both provided with arc transition parts for increasing the stressed area and reducing the water flow/air flow impact noise.

Preferably, an overflow port for water flowing into the guide pipe is arranged on the side wall of the upper end of the guide pipe.

Preferably, the edge of the lower cover shell is also provided with at least two second fixing supports which are uniformly arranged around the lower cover shell.

Preferably, the spacer is made of a rubber material having a tensile elongation of not less than 450%.

The other technical scheme of the invention is realized as follows: the utility model provides a gas indirect heating equipment, includes indirect heating equipment body and foretell control by temperature change cabin, the control by temperature change cabin is through second fixed bolster fixed mounting above that in the indirect heating equipment body.

Compared with the prior art, the temperature compensation assembly is arranged on the side wall of the lower cover shell assembly, so that hot water or cold water flowing into the temperature control cabin is effectively subjected to heat compensation or cold compensation, the temperature of the outlet water is constant within a certain temperature range, the temperature fluctuation of the water flow flowing out of the temperature control cabin is reduced, the problem of sudden cooling and sudden heating is solved, the bathing scene requirements of users are met, and the use comfort of the users is improved; in addition, the protection of all components forming the temperature control cabin in a low-temperature environment is effectively realized, and the problem of frost cracking easily in the low-temperature environment is avoided.

Drawings

Fig. 1 is a longitudinal sectional view of a temperature control cabin with a temperature compensation function according to embodiment 1 of the present invention;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

fig. 3 is a front view of a temperature control cabin with a temperature compensation function according to embodiment 1 of the present invention;

fig. 4 is a top view of a temperature control chamber with a temperature compensation function according to embodiment 1 of the present invention;

FIG. 5 is a partial enlarged view of portion B of FIG. 4;

fig. 6 is a schematic structural view of a cooling/heating plate in a temperature control cabin with a temperature compensation function according to embodiment 1 of the present invention;

Fig. 7 is a schematic view of the direction of an electrode of a cooling/heating plate in a temperature control cabin with a temperature compensation function according to embodiment 1 of the present invention;

fig. 8 is a schematic view of an electrode direction in heating of a cooling and heating plate in a temperature control cabin with a temperature compensation function according to embodiment 1 of the present invention;

fig. 9 is a graph showing a refrigeration process of a refrigeration and heating plate in a temperature control compartment with a temperature compensation function according to embodiment 1 of the present invention;

fig. 10 is a heating process curve diagram of a cooling and heating plate in a temperature control cabin with a temperature compensation function according to embodiment 1 of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it is to be understood that the terms "vertical", "lateral", "longitudinal", "front", "rear", "left", "right", "upper", "lower", "horizontal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description of the present invention, and do not mean that the device or member to which the present invention is directed must have a specific orientation or position, and thus, cannot be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

The temperature control cabin with the temperature compensation function provided by the embodiment 1 of the invention is applied to gas heat exchange equipment as shown in fig. 1 and 3, and comprises an upper cover shell 1, a flow guide pipe 2, a temperature compensation assembly 3, a lower cover shell assembly 4 with a water inlet arranged on the side wall and a control assembly; the upper cover shell 1 is connected with the lower cover shell component 4 to form a water storage cavity, the flow guide pipe 2 is arranged in the water storage cavity, the lower end of the flow guide pipe is hermetically connected with the bottom of the lower cover shell component 4, the temperature compensation component 3 is arranged on the outer wall of the lower cover shell component 4, and the control component is electrically connected with the temperature compensation component 3 and used for performing temperature compensation on water in the water storage cavity; the method specifically comprises the following steps: the control assembly adjusts the electrode direction of the temperature compensation assembly according to the refrigeration or heating requirement of a user and is used for performing temperature compensation on water in the water storage cavity.

After adopting above-mentioned scheme, through set up temperature compensation subassembly 3 on the lateral wall at lower cover casing subassembly 4, effectual realized carrying out thermal compensation or cold compensation to the hot water or the cold water that flow in this temperature control cabin, make the leaving water temperature invariant in a certain temperature range, reduced the temperature fluctuation of the rivers that flow out the temperature control cabin, solved the problem of neglecting cold and neglecting hot to satisfy user's bathing scene demand, improved user's use travelling comfort.

Further, as shown in fig. 1, the temperature control cabin further comprises a spacer 5 capable of generating elastic deformation, the diaphragm 5 is arranged between the upper cover shell 1 and the lower cover shell assembly 4, an air storage cavity is formed between the upper cover shell 1 and the diaphragm 5, a water storage cavity is formed between the lower cover shell assembly 4 and the diaphragm 5, and the flow guide pipe 2 is arranged in the water storage cavity; the spacer 5 is made of a rubber material having a tensile elongation of not less than 450%, wherein the rubber material may be IIR (butyl rubber), NBR (nitrile rubber), NR (natural rubber), or SBR (styrene-butadiene rubber).

Further, as shown in fig. 1, the lower cover housing assembly 4 includes a lower cover housing 41 and a cylinder 42, the cylinder 42 is disposed above the lower cover housing 41, the cylinder 42 and the diaphragm 5 are sequentially connected to form a water storage cavity, and the water inlet and the temperature compensation assembly 3 are disposed on an outer wall of the cylinder 42.

Through set up barrel 42 between upper cover casing 1 and lower cover casing 41, not only the effectual volume that increases the water storage cavity, but also be convenient for the operating personnel to install temperature compensation assembly 3.

Further, as shown in fig. 5, the temperature compensation assembly 3 includes a cooling and heating sheet 31, a heat transfer pad 32, a first fixing bracket 33, and a heat dissipation unit 34, wherein the heat transfer pad 32, the cooling and heating sheet 31, and the heat dissipation unit 34 are sequentially and fixedly disposed on the outer side wall of the cylinder 42 from inside to outside through the first fixing bracket 33; the heat transfer pad 32 may also be referred to as a heat transfer medium, and the heat transfer pad 32 may be replaced by a copper pad or other material with high thermal conductivity (thermal conductivity);

in addition, temperature compensation subassembly 3 can be when the temperature of intaking is higher to the inside rivers handle of cooling down to realize the purpose to the demand of low-temperature water under the hot weather, in addition, through adopting temperature compensation subassembly 3 to carry out temperature compensation's mode to the water in the control by temperature change cabin, its temperature compensation interval is big, and temperature drop time is fast, and the compensation effect is obvious.

Further, as shown in fig. 5, the heat dissipating unit 34 includes a heat dissipating plate 341 and a heat dissipating pin 342, and the heat dissipating pin 342 is disposed on a side of the heat dissipating plate 341 away from the cooling and heating sheet 31; the heat dissipation plate 341 is fixedly connected to the first fixing bracket 33 by a screw; the heat sink 341 is made of Cu with high thermal conductivity or other materials with excellent heat dissipation performance, and the heat sink 341 may also be a planar heat sink structure. The heat dissipation pins 342 are arranged on one side of the heat dissipation plate 341 away from the refrigerating and heating sheet 31, so that the heat dissipation speed can be effectively improved, and the temperature reduction efficiency can be improved; the heat dissipation pins are preferably matrix type heat dissipation pins.

Further, as shown in fig. 1 and 3, the temperature control chamber further includes a pressure relief assembly 6, and the pressure relief assembly 6 is disposed on the upper cover casing 1 for performing safe pressure relief when the pressure in the air storage chamber reaches overpressure.

Thus, the pressure relief assembly 6 is arranged on the upper cover shell 1, so that the purpose of safe pressure relief when overpressure is achieved after the pressure intensity is changed due to the volume compression or expansion of the air storage cavity in the temperature control cabin caused by the change of water temperature is effectively achieved, the safety coefficient of the whole temperature control cabin is effectively improved, and the occurrence of potential safety hazards is reduced; in addition, the pressure relief assembly 6 can also fully digest the change of the water volume and the change of the pressure of the internal closed space caused by the rising or the lowering of the internal water temperature, thereby playing a role in protecting all components forming the temperature control cabin.

Further, as shown in fig. 6, the cooling/heating sheet 31 includes a first insulating base 311, a second insulating base 312, a first conductor layer 313, a second conductor layer 314, a P-type semiconductor block 315, and an N-type semiconductor block 316, the first insulating base 311 and the second insulating base 312 are disposed in parallel with each other, the first conductor layer 313 and the second conductor layer 314 are respectively disposed inside the first insulating base 311 and the second insulating base 312 so as to face each other, the P-type semiconductor block 315 and the N-type semiconductor block 316 are disposed between the first conductor layer 313 and the second conductor layer 314 and abut against each other, and a gap is provided between the second conductor layers 314; the purpose of the gap is to enable the cooling and heating fins 31 to form a current loop; the materials of the first insulating substrate 311 and the second insulating substrate 312 are mainly selected from the insulation, heat conduction and temperature resistance conditions, and are preferably ceramic substrates; the intermediate first 313 and second 314 conductor layers are preferably Cu conductor layers.

In addition, the using principle of the cooling and heating sheet 31 is as follows: by applying a current in a certain direction to the N-type semiconductor block 316 (abbreviated as N-level) and the P-type semiconductor block 315 (abbreviated as P-level), electrons accumulated in the N-level and holes accumulated in the P-level will generate directional movement, thereby forming a loop current, and at the same time, heat variation will occur at the junction of the two poles (P-level and N-level), as shown in fig. 7 and 8, and fig. 6 and 7 show the temperature variation of the first insulating substrate 311 and the second insulating substrate 312 when power in different directions is input to the N-level and the P-level: when the N-level is connected to the positive electrode, the junction absorbs heat to lower the temperature of the peripheral space, the heat loss in this region is at the cold end (i.e., the upper region of the first insulating substrate 311), and the heat accumulation on the opposite side is at the hot end (i.e., the lower region of the second insulating substrate 312); when the N-level negative electrode is connected, heat is released at the joint end, so that the temperature of the peripheral space position of the joint end is increased, the heat increase of the area is at the hot end (namely, the upper area of the first insulating base 311), and the heat accumulation of the opposite side of the area is at the cold end (namely, the lower area of the second insulating base 312); the different power of the cooling and heating plate 31 and the number of pairs of the P-type semiconductor block 315 and the N-type semiconductor block 316 are selected to realize different temperature difference requirements, for example, the cooling and heating rate can reach 14.8 under the conditions of selecting input voltages DC 5V and 4A, and the maximum temperature difference can reach 67K.

The refrigeration principle of the refrigeration and heating sheet 31 is as follows: when refrigeration is needed, positive voltage is applied to the N-level, the connection end of the refrigeration and heating sheet 31 is a cold end, the heat dissipated by the water inside the temperature control chamber is balanced with the heat change of air heating and hot end heating, as shown in fig. 9, the initial temperature of the water inside the temperature control chamber is Tmax, and after the refrigeration and heating sheet 41 works, the heat of the water inside the temperature control chamber is further dissipated due to a temperature exchange phenomenon, and the temperature is reduced to T0; after a certain time, the temperature difference reaches the required temperature T0, the input voltage and current are kept unchanged, the water temperature, the temperature of the cold end and the temperature of the surrounding air are kept constant, the temperature difference is close to 0, and the temperature is not reduced any more.

The heating principle of the cooling and heating sheet 31 is as follows: when the temperature control device is not started, the water flowing into the whole device with the temperature Tmin is too low, the frost cracking risk can occur, at the moment, the control assembly outputs N levels as negative poles through the phase-change rectifying element, at the moment, the cross-connecting end of the refrigerating and heating sheet 31 is a hot end, water in the temperature control cabin is heated, mainly high temperature on the outer side flows to the low-temperature control cabin, when the required temperature point is reached, balance can be achieved, namely as shown in figure 10, the temperature is not increased after the temperature Tmin is increased to T1, and the state is kept.

Further, as shown in fig. 1, a water inlet joint 421 is disposed at a water inlet on the cylinder 42, a water outlet is disposed at a position corresponding to the lower end of the flow guide tube 2 on the lower cover shell 41, and a water outlet joint 411 connected to the flow guide tube 2 is disposed at the water outlet.

Further, the water inlet joint 421 is in an "L" shape; through setting up into water connector 421 for "L" type, the section passageway of intaking is the horizontal direction promptly, goes out the water section passageway opening and down, makes the water that flows into this temperature control cabin smoothly flow into to the water storage cavity in this way to more effectual water to the water in the water storage cavity carries out temperature compensation.

Further, as shown in fig. 2, a flanging flange 11 extends outwards from the edge of the upper cover shell 1, a flange 422 extends outwards from the upper edge of the cylinder 42, the edge of the diaphragm 5 abuts against the flange 422, and the flanging flange 11 covers the edge of the pressing diaphragm 5 and the flange 422.

The flange 11 on the upper cover shell 1 is adopted to cover the edge of the buckling diaphragm 5 and the flange 422 on the cylinder 42, so that the problem of water leakage of the temperature control cabin is effectively avoided, and the reliability of connection between the upper cover shell of the temperature control cabin and the cylinder 42 is also enhanced.

Further, as shown in fig. 1 and 3, the upper cover housing 1 and the lower cover housing 41 are provided with arc transition portions for increasing the force-bearing area and reducing the water/air impact noise.

The arc transition parts are arranged on the upper cover shell 1 and the lower cover shell 41, so that the stress area of the temperature control cabin body is effectively increased, the fluid pressure in the temperature control cabin is reduced, and the compressive strength of the gas storage cavity and the water storage cavity is improved.

Further, as shown in fig. 1, an overflow port 21 for water to flow into the draft tube 2 is provided on the upper end side wall of the draft tube 2; in addition, the upper end face of the draft tube 2 is welded with a closed end cover.

Further, as shown in fig. 4, at least two second fixing brackets 412 are further disposed at the edge of the lower cover casing 41 and are uniformly disposed around the lower cover casing 41.

In addition, the upper cover shell 1, the cylinder 42, the lower cover shell 41, the water inlet joint 421, the water outlet joint 411 and the flow guide pipe 2 which form the temperature control cabin in the embodiment 1 are all made of stainless steel materials, and are formed by adopting an integral brazing process, so that the temperature control cabin is extremely strong in corrosion resistance. The use principle of the temperature control cabin with the temperature compensation function provided by the embodiment 1 is as follows: after water flows into the temperature control cabin, setting refrigeration or heating requirements according to use conditions; when low-temperature cold water is needed, the cold end is in contact with the temperature control cabin, the temperature of the water in the cabin body is reduced through temperature compensation, meanwhile, the high-efficiency heat dissipation of the hot end can promote the realization of temperature reduction, and the temperature reduction rate is accelerated; otherwise, when the low-temperature water in the cabin body needs to be heated, the contact end is set as the hot end, so that the water in the cabin body is heated.

The working conditions of the temperature control cabin with the temperature compensation function provided by this embodiment 1 are as follows: no matter the water in the water storage cabin body is in a static state or a flowing state, the temperature compensation can be continuously carried out, the temperature reaching the water outlet at the upper end of the flow guide pipe is finally a stable value, and the fluctuation of the temperature of the water flowing out of the temperature control cabin body can be effectively reduced.

Example 2

The gas heat exchange equipment that this embodiment 2 provided, including the indirect heating equipment body and the control by temperature change cabin in embodiment 1, the control by temperature change cabin is through second fixed bolster 412 fixed mounting on it in the indirect heating equipment body.

Through applying the temperature control cabin in embodiment 1 to present heat transfer equipment this internally (like gas heater body or heating stove body), effectual realized carrying out thermal compensation or cold compensation to the hot water or cold water that flow into this gas heat transfer equipment for the temperature of water that comes out from gas heat transfer equipment is invariable in a certain temperature range, has solved the problem of neglecting cold and neglecting hot, thereby satisfies user's bathing scene demand, improves user's use travelling comfort.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (12)

1. A temperature control cabin with a temperature compensation function is applied to gas heat exchange equipment and is characterized by comprising an upper cover shell (1), a flow guide pipe (2), a temperature compensation assembly (3), a lower cover shell assembly (4) with a water inlet formed in the side wall and a control assembly; the upper cover shell (1) is connected with the lower cover shell component (4) to form a water storage cavity, the flow guide pipe (2) is arranged in the water storage cavity, the lower end of the flow guide pipe is connected with the bottom of the lower cover shell component (4) in a sealing mode, the temperature compensation component (3) is arranged on the outer wall of the lower cover shell component (4), and the control component is electrically connected with the temperature compensation component (3) and used for compensating the temperature of water in the water storage cavity.

2. The temperature control cabin with the temperature compensation function according to claim 1, further comprising a spacer (5) capable of generating elastic deformation, wherein the diaphragm (5) is arranged between the upper cover shell (1) and the lower cover shell assembly (4), an air storage cavity is formed between the upper cover shell (1) and the diaphragm (5), a water storage cavity is formed between the lower cover shell assembly (4) and the diaphragm (5), and the flow guide pipe (2) is arranged in the water storage cavity.

3. The temperature control cabin with the temperature compensation function according to claim 2, wherein the lower cover shell assembly (4) comprises a lower cover shell (41) and a barrel (42), the barrel (42) is arranged above the lower cover shell (41), the barrel (42) and the diaphragm (5) are sequentially connected to form a water storage cavity, and the water inlet and the temperature compensation assembly (3) are both arranged on the outer wall of the barrel (42).

4. The temperature control cabin with the temperature compensation function according to claim 3, wherein the temperature compensation assembly (3) comprises a refrigerating and heating sheet (31), a heat transfer pad (32), a first fixing support (33) and a heat dissipation unit (34), and the heat transfer pad (32), the refrigerating and heating sheet (31) and the heat dissipation unit (34) are fixedly arranged on the outer side wall of the barrel (42) sequentially from inside to outside through the first fixing support (33).

5. The temperature control cabin with the temperature compensation function according to claim 4, wherein the heat dissipation unit (34) comprises a heat dissipation plate (341) and heat dissipation pins (342), and the heat dissipation pins (342) are arranged on one side of the heat dissipation plate (341) far away from the refrigerating and heating sheet (31).

6. The temperature-controlled cabin with the temperature compensation function according to claim 5, wherein the cooling and heating sheet (31) comprises a first insulating base body (311), a second insulating base body (312), a first conductor layer (313), a second conductor layer (314), a P-type semiconductor block (315) and an N-type semiconductor block (316), the first insulating base body (311) and the second insulating base body (312) are arranged in parallel, the first conductor layer (313) and the second conductor layer (314) are respectively and oppositely arranged on the inner sides of the first insulating base body (311) and the second insulating base body (312), the P-type semiconductor block (315) and the N-type semiconductor block (316) are arranged between the first conductor layer (313) and the second conductor layer (314) and abut against each other, and a gap is arranged between the second conductor layer (314).

7. The temperature control cabin with the temperature compensation function according to any one of claims 3 to 6, wherein a water inlet connector (421) is arranged at a water inlet on the cylinder (42), a water outlet is further arranged on the lower cover shell (41) at a position corresponding to the lower end of the flow guide pipe (2), and a water outlet connector (411) connected with the flow guide pipe (2) is arranged at the water outlet.

8. The temperature control cabin with the temperature compensation function according to claim 7, wherein a flanging flange (11) extends outwards from the edge of the upper cover shell (1), a flange (422) extends outwards from the upper edge of the cylinder body (42), the edge of the diaphragm (5) abuts against the flange (422), and the flanging flange (11) covers the flange (422) and the edge of the buckling diaphragm (5).

9. The temperature control cabin with the temperature compensation function according to claim 8, wherein the upper cover shell (1) and the lower cover shell (41) are provided with arc transition parts for increasing the stress area and reducing the water flow/air flow impact noise.

10. The temperature-controlled cabin with the function of temperature compensation according to claim 9, characterized in that the upper side wall of the draft tube (2) is provided with an overflow port (21) for water flowing into the draft tube (2).

11. The temperature control cabin with the temperature compensation function according to any one of claims 8 to 10, wherein at least two second fixing brackets (412) are further arranged at the edge of the lower cover shell (41) and are uniformly arranged around the lower cover shell (41).

12. A gas fired heat exchange unit comprising a heat exchange unit body and a temperature controlled compartment as claimed in any one of claims 1 to 11 mounted within the heat exchange unit body.

Images