CN216522640U - Cold and hot integral type temperature machine - Google Patents

Abstract

The utility model relates to a cold and hot integral type temperature machine for the technical field of temperature machine, it includes heating circuit, cooling circuit and cooling circuit, the cooling circuit includes the cold water storage cistern, cooling circuit is including the first branch pipe of intercommunication on the compressor, the other end and the cold water storage cistern of first branch pipe are linked together, the intercommunication has the second branch pipe on the compressor, the second branch pipe communicates in proper order has condenser, expansion pump, first branch pipe is linked together with the second branch pipe, the intercommunication has the first condenser pipe that is used for pouring into the cooling water and the second condenser pipe that is used for discharging the comdenstion water on the condenser. The application has the technical effects that: the gas liquefaction heat release process of the first condensation pipe and the second condensation pipe at high temperature and high pressure is reduced, the first condensation pipe and the second condensation pipe are heated to cause the high temperature and high pressure gas to be liquefied and released heat, and therefore the cooling efficiency of the cooling loop is reduced.

Description

Cold and hot integral type temperature machine

Technical Field

The application relates to a temperature machine, especially relates to a cold and hot integral type temperature machine.

Background

The water temperature machine is one of the mould temperature machines, which is called as a mould temperature controller, the mould temperature machine is a mechanical device with heating and cooling functions and used for industrial temperature control, and the mould temperature machine heats in an electric heating mode and controls the temperature by a temperature controller; the temperature is controlled by an external cooling source, and the on-off of the cooling electromagnetic valve is controlled.

The temperature machine is at the in-process of control cooling, generally pours into the return circuit with the cold water in the cold water tank, takes away the heat through the high specific heat capacity of water, at cold water endless in-process, can adopt the mode that the fan bloied, accelerates the cooling efficiency of circulating water through the condenser.

In the use process of the water chiller, the inventor finds that the technology has at least the following problems: the cooling efficiency of the circulating water is low by using the fan, so that the cooling efficiency of the water temperature machine is poor.

SUMMERY OF THE UTILITY MODEL

In order to improve the relatively poor problem that leads to temperature machine cooling efficiency difference of forced air cooling effect, the application provides a cold and hot integral type temperature machine adopts following technical scheme: the utility model provides a cold and hot integral type temperature machine, includes heating circuit, cooling circuit and cooling circuit, the cooling circuit includes the cold water storage cistern, cooling circuit is including the first branch pipe of intercommunication on the compressor, the other end and the cold water storage cistern of first branch pipe are linked together, and the intercommunication has the second branch pipe on the compressor, the second branch pipe communicates in proper order has condenser and expansion pump, first branch pipe is linked together with the second branch pipe, the intercommunication has the first condenser pipe that is used for pouring into the cooling water and the second condenser pipe that is used for the discharge comdenstion water on the condenser.

Through the technical scheme, carry out refrigerated in-process to the cold water storage cistern, compress coolant gas through the compressor, export the high-temperature high-pressure gas of condenser, the high-temperature high-pressure gas gets into behind the condensing engine liquefaction exothermic, export the return circuit in the cold water storage cistern after the expansion pump expands, run into hotter cold water evaporation endothermic in the cold water storage cistern, the realization is to the cooling operation of cold water storage cistern, through first condenser pipe and the second condenser pipe of intercommunication on the condenser, make cold water constantly circulate in the condenser, first condenser pipe and the exothermic in-process of second condenser pipe at the high-temperature high-pressure gas liquefaction have been reduced, first condenser pipe and second condenser pipe are heated and lead to the unable liquefaction of high-temperature high-pressure gas exothermic, thereby reduce cooling circuit's cooling efficiency.

In a specific embodiment, the heating circuit comprises a heater, a first circulation pipe is communicated with the heater, a first ball valve is communicated with the first circulation pipe, a second circulation pipe is communicated with the heater, a first circulation pump, an exhaust valve and a second ball valve are communicated with the second circulation pipe, the first circulation pipe is communicated with the second circulation pipe, a third circulation pipe is communicated between the first circulation pipe and the second circulation pipe, one end of the third circulation pipe is arranged at the communication position between the first ball valve and the heater, and the other end of the third circulation pipe is arranged at the communication position between the first circulation pump and the exhaust valve.

Through the technical scheme, in the working process of the heating loop, firstly, water flow in the heating loop is heated through the heater, the heated water flow is conveyed to the first ball valve through the first circulating pipe, the heating equipment is heated through the first ball valve, then, the heated water flow passes through the second circulating pipe, the water flow sequentially passes through the second ball valve and the exhaust valve under the driving of the second circulating pump and flows back to the heater, and when the heating equipment is required to be heated, the heating loop can be continuously circulated to heat the heating equipment by starting the first circulating pump and the heater.

In a specific possible embodiment, the cold water tank is communicated with a first cooling pipe, the first cooling pipe is sequentially communicated with a one-way valve and a cooling electromagnetic valve, the first cooling pipe is communicated with the exhaust valve, the cold water tank is communicated with a second cooling pipe, the second cooling pipe is communicated with a second circulating pump, the second cooling pipe is communicated with a second circulating pipe, the communication position of the second cooling pipe and the second circulating pipe is arranged at the connection position of the first circulating pump and the exhaust valve, a third cooling pipe is communicated between the first cooling pipe and the second cooling pipe, one end of the third cooling pipe is arranged at the communication position between the cold water tank and the one-way valve, and the other end of the third cooling pipe is arranged at the communication position between the second circulating pipe and the cooling electromagnetic valve.

Through above-mentioned technical scheme, when needs are cooled down the operation to equipment, the staff can close the heater and make the cold water in the cold water tank get into the second circulating pipe through the second cooling pipe and then when heating circuit inner loop to discharge valve, flow back to the cold water tank through the first cooling pipe that is linked together with discharge valve for cooling circuit can cool down equipment.

In a specific embodiment, the condenser comprises an installation pipe, an air inlet hole is formed in the installation pipe, an air outlet hole is formed in the installation pipe, a plurality of condensation pipes penetrate through the installation pipe, the condensation pipes partially extend into the installation pipe, a disassembly groove is formed in the installation pipe, and a sealing plate used for sealing the disassembly groove is arranged on the disassembly groove.

Through above-mentioned technical scheme, at the condenser to the high-temperature high-pressure in-process that carries out the liquefaction cooling, when the condenser pipe appears damaging, can lift off the closing plate from dismantling the groove through the mode of drawing the dismantlement groove to the staff restores or changes the condenser pipe.

In a specific implementation scheme, the sealing plate is provided with a plurality of connecting bolts in a penetrating and threaded connection manner, the mounting pipe is provided with connecting grooves matched with the connecting bolts, the connecting bolts are in threaded connection in the connecting grooves, the sealing plate is provided with a rubber pad, and the rubber bottom is abutted between the sealing plate and the mounting pipe.

Through the technical scheme, when the closing plate needs to be disassembled, a worker can take the connecting bolt out of the connecting groove in a mode of rotating the connecting bolt, and then pull the closing plate to disassemble the closing plate from the disassembling groove, so that the worker can conveniently disassemble the condensing pipe; the rubber pad reduces the possibility that water flow in the condenser flows out from the gap between the closing plate and the mounting pipe, so that the connection stability between the closing plate and the mounting pipe is improved.

In a specific implementation scheme, a plurality of installation sleeves are arranged on the inner wall of each installation pipe, a plurality of installation holes matched with the condensation pipes are formed in the installation sleeves, indication blocks are arranged on the condensation pipes, indication grooves matched with the indication blocks are formed in the installation sleeves, the indication blocks are abutted against the indication grooves, limit rods penetrate through the installation sleeves, limit grooves matched with the limit rods are formed in the indication blocks, and the limit rods are abutted against the limit grooves.

Through the technical scheme, when the condenser pipe is installed to needs, the staff can at first stretch into the condenser pipe in the installation from the dismantlement groove, then make the condenser pipe support tightly each other with the pore wall of mounting hole through the mode of pressing the condenser pipe, support tightly each other until instructing the piece and instructing the groove, then press the gag lever post and make the gag lever post support tightly at the spacing inslot, reduced the condenser pipe and sheathe the possibility that breaks away from the installation under the exogenic action, thereby promoted the stability of being connected between condenser pipe and the installation cover.

In a specific implementation scheme, a rotating shaft is rotatably connected to the limiting rod, a plurality of mounting plates are arranged on the rotating shaft, iron plates are arranged on the mounting plates, magnetic plates matched with the iron plates are arranged on the mounting sleeves, and the iron plates and the magnetic plates are mutually abutted.

Through above-mentioned technical scheme, after the instruction pole supports tightly each other with the instruction groove, the staff can make magnetic sheet and iron plate support tightly each other through the mode of drawing the mounting panel, has reduced the gag lever post and has produced the displacement of relative spacing groove under the exogenic action to the stability of being connected between gag lever post and the installation cover has been promoted.

In a specific embodiment, the connecting groove is provided with a guide groove arranged obliquely along the circumference.

Through above-mentioned technical scheme, at the in-process of installation connecting bolt, the staff can be through at first supporting connecting bolt tightly on the guide way, then under the guide of guide way quick convenient with the spread groove align each other for the staff can be quick convenient with connecting bolt threaded connection in the spread groove.

In summary, the present application includes at least one of the following beneficial technical effects:

1. in the process of cooling the cold water tank, the refrigerant gas is compressed through the compressor, high-temperature and high-pressure gas is output to the condenser, the high-temperature and high-pressure gas is liquefied and released heat after entering the condenser, and is output to a loop in the cold water tank after being expanded through the expansion pump, and the cold water tank is cooled when encountering hotter cold water evaporation and absorption, so that the cold water tank is continuously circulated in the condenser through the first condenser pipe and the second condenser pipe which are communicated with the condenser, the problem that the high-temperature and high-pressure gas cannot be liquefied and released heat when the first condenser pipe and the second condenser pipe are liquefied and released heat is reduced when the first condenser pipe and the second condenser pipe are heated is solved, and the cooling efficiency of the cooling loop is reduced;

2. after the indication rod and the indication groove are tightly abutted, the magnetic plate and the iron plate are tightly abutted by each other by a worker in a mode of drawing the mounting plate and the second mounting plate, so that the displacement of the limiting rod, which generates a relative limiting groove under the action of external force, is reduced, and the connection stability between the limiting rod and the mounting sleeve is improved.

Drawings

Fig. 1 is a schematic piping diagram of example 1 of the present application.

Fig. 2 is an overall schematic view of embodiment 2 of the present application.

Fig. 3 is an exploded view schematically showing the connection relationship between the connection bolt and the connection groove in embodiment 2 of the present application.

Fig. 4 is an enlarged schematic view at a in fig. 3.

Fig. 5 is a schematic cross-sectional view for embodying the mounting sleeve in embodiment 2 of the present application.

Fig. 6 is an exploded view schematically showing the connection relationship between the condensation pipe and the mounting sleeve in embodiment 2 of the present application.

Reference numerals: 1. a heating circuit; 2. a cooling loop; 3. a cooling circuit; 4. a cold water tank; 5. a first branch pipe; 6. a second branch pipe; 7. a condenser; 8. an expansion pump; 9. a first condenser pipe; 10. a second condenser pipe; 11. a heater; 12. a first circulation pipe; 13. a first ball valve; 14. a second circulation pipe; 15. a first circulation pump; 16. an exhaust valve; 17. a second ball valve; 18. a third circulation pipe; 19. a first cooling pipe; 20. a one-way valve; 21. cooling the electromagnetic valve; 22. a second cooling pipe; 23. a second circulation pump; 24. a third cooling pipe; 25. installing a pipe; 26. an air inlet; 27. an air outlet; 28. a condenser tube; 29. disassembling the groove; 30. a closing plate; 31. a connecting bolt; 32. connecting grooves; 33. a rubber pad; 34. installing a sleeve; 35. mounting holes; 36. an indication block; 37. an indication groove; 38. a limiting rod; 39. a limiting groove; 40. a rotating shaft; 41. mounting a plate; 42. an iron plate; 43. a magnetic plate; 44. a guide groove; 45. a compressor.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses cold and hot integral type temperature machine.

Example 1:

as shown in fig. 1, the cold and hot integrated water temperature machine comprises a heating circuit 1, a cooling circuit 2 and a cooling circuit 3, wherein the cooling circuit 3 comprises a cold water tank 4, the cooling circuit 3 is partially arranged in the cold water tank 4, and the cooling circuit 3 is communicated with the heating circuit 1.

As shown in fig. 1, the heating circuit 1 includes a heater 11, and a first exhaust valve 16 is connected to the heater 11, so as to reduce the possibility that the internal pressure of the heater 11 is too high and then damaged due to too much gas in the heater 11; the heater 11 is communicated with a first circulating pipe 12, the first circulating pipe 12 is communicated with a pressure display used for detecting the internal pressure of the first circulating pipe 12, the first circulating pipe 12 is also communicated with a first temperature sensor used for detecting the internal temperature of the first circulating pipe 12, the first circulating pipe 12 is communicated with a first ball valve 13, the first ball valve 13 is communicated with a second circulating pipe 14, the second circulating pipe 14 is communicated with a first filter, the second circulating pipe 14 is also communicated with a second ball valve 17, the second circulating pipe 14 is communicated with a second temperature sensor used for detecting the internal temperature of the second circulating pipe 14, the second circulating pipe 14 is communicated with a second exhaust valve 16, the second circulating pipe 14 is also communicated with a circulating pump, the second circulating pipe 14 is also communicated with a high-pressure protector, the second circulating pipe 14 is communicated with the heater 11, and a third circulating pipe 18 is communicated between the first circulating pipe 12 and the second circulating pipe 14, one end of the third circulation pipe 18 communicates with a junction between the first temperature sensor and the first ball valve 13, and the other end of the third circulation pipe 18 communicates with a junction between the second temperature sensor and the second exhaust valve 16. Therefore, when the equipment needs to be heated, the water flow can be heated by the heater 11, and the arrangement of the first exhaust valve 16 reduces the possibility of damage caused by excessive internal pressure due to evaporation of the water flow in the heater 11; the arrangement of the pressure sensor and the temperature sensor enables a worker to quickly and conveniently know the pressure and temperature conditions inside the first circulating pipe 12; the first ball valve 13 and the second ball valve 17 can control the on-off of the heating loop 1 of the equipment, so that the heating loop 1 can be heated to a specified temperature and then the equipment is heated.

As shown in fig. 1, the second exhaust valve 16 is communicated with a first cooling pipe 19, the first cooling pipe 19 is communicated with a second filter, the first cooling pipe 19 is further communicated with a cooling electromagnetic valve 21, the first cooling pipe 19 is communicated with a one-way valve 20, the first cooling pipe 19 is communicated with the cold water tank 4, the cold water tank 4 is communicated with a second cooling pipe 22, the second cooling pipe 22 is communicated with a second circulating pump 23, the second cooling pipe 22 is communicated with a third filter, the second cooling pipe 22 is communicated with a low-pressure protector, the second cooling pipe 22 is communicated with the second circulating pipe 14, the communication position is arranged between the high-pressure protector and the second exhaust valve 16, a third cooling pipe 24 is communicated between the first cooling pipe 19 and the second cooling pipe 22, one end of the third cooling pipe 24 is communicated between the cold water tank 4 and the one-way valve 20, and the other end of the third cooling pipe 24 is communicated between the second circulating pump 23 and the third filter. Therefore, when the equipment needs to be cooled down, the worker can first turn off the heater 11, inject the cold water in the cold water tank 4 into the heating circuit 1 through the second circulating pump 23, and cool down the equipment, the one-way valve 20 is set to be closed after the cold water between the heating circuit 1 and the cooling circuit 2 is filled, and the cold water pumped out from the second circulating pump 23 directly flows back into the cold water tank 4 through the first cooling pipe 19.

As shown in fig. 1, the cooling circuit 3 includes a compressor 45, the compressor 45 is communicated with a first branch pipe 5, the first branch pipe 5 is communicated with the cold water tank 4, the compressor 45 is also communicated with a second branch pipe 6, the second branch pipe 6 is communicated with a condenser 7, the condenser 7 is communicated with a first condensation pipe 9 for injecting cooling water and a second condensation pipe 10 for discharging condensed water, the first condensation pipe 9 and the second condensation pipe 10 are communicated in the condenser 7, and are arranged in a serpentine shape in the condenser 7; the condenser 7 keeps the temperature of the first condensation pipe 9 and the second condensation pipe 10 by circularly injecting cold water into the first condensation pipe 9 and the second condensation pipe 10, so that the first condensation pipe 9 and the second condensation pipe 10 can stably carry out liquefaction and heat release operation on high-temperature and high-pressure gas; the second branch pipe 6 is also communicated with a fourth filter, the second branch pipe 6 is communicated with the first branch pipe 5 in the cold water tank 4 through an expansion pump 8, the first branch pipe 5 and the second branch pipe 6 are arranged in a snake shape at the part of the cold water tank 4, the contact area of the first branch pipe 5 and the cold water in the cold water tank 4 is increased, and therefore the cooling effect on the cold water tank 4 is improved; when the cold water in the cold water tank 4 needs to be cooled down, the staff can compress the coolant to form high-temperature and high-pressure gas by starting the compressor 45, then the high-temperature and high-pressure gas is injected into the condenser 7, the heat is liquefied in the condenser 7 and released, then the liquefied heat is injected into the cold water tank 4 through the fourth filter and the expansion pump 8, and the coolant is heated and evaporated in the cold water tank 4 to absorb the heat, so that the temperature of the cold water in the cold water tank 4 is reduced.

The implementation principle of the embodiment 1 of the application is as follows: when the equipment needs to be heated, a worker starts the heater 11, starts the second circulating pump 23 and the first circulating pump 15 to inject cold water into the heating loop 1, heats the cold water through the heater 11, and circularly heats the equipment after the equipment is heated to a specified temperature;

when needs are cooled down to equipment, the staff can start the cold water injection heating return circuit 1 of second circulating pump 23 in with cold water tank 4, and close heater 11, start first circulating pump 15 and make cold water get back to in cold water tank 4 through first cooling tube 19 at heating return circuit 1 mesocycle at last, at the cooling in-process, the staff can start compressor 45 and handle the cooling to the hot water of cold water tank 4 that flows back, make cold water tank 4 keep low temperature, cool down the operation to condenser 7 through first condenser pipe 9 and second condenser pipe 10, thereby the cooling efficiency of condenser 7 has been promoted.

Example 2:

as shown in fig. 2, 3 and 4, the difference between embodiment 2 and embodiment 1 of the present application is that: condenser 7 includes mounting tube 25, inlet port 26 and venthole 27 have been seted up on the mounting tube 25, wear to be equipped with a plurality of condenser pipes 28 on the mounting tube 25, condenser pipe 28 part extends to in the mounting tube 25, and condenser pipe 28 in mounting tube 25 is snakelike setting, dismounting groove 29 has been seted up on the mounting tube 25, the diameter of condenser pipe 28 is less than dismounting groove 29's width, be equipped with the closed plate 30 that is used for sealing dismounting groove 29 on the mounting tube 25, wear to establish and threaded connection has a plurality of connecting bolt 31 on the closed plate 30, set up a plurality ofly on the mounting tube 25 and connecting bolt 31 assorted spread groove 32, spread groove 32 sets up the guide way 44 that the slope set up along the periphery, it has size and closed plate 30 assorted rubber pad 33 to bond on the closed plate 30, rubber pad 33 is supported tightly between closed plate 30 and mounting tube 25. Therefore, when the condenser tube 28 needs to be disassembled, a worker can first rotate the connecting bolt 31 to remove the connecting bolt 31 from the connecting groove 32, and then pull the plate closing plate 30 to remove the rubber gasket 33 and the closing plate 30 from the mounting tube 25, so that the worker can repair or replace the condenser tube 28.

As shown in fig. 5 and 6, a plurality of mounting sleeves 34 are fixedly connected to the inner wall of the mounting tube 25, a mounting hole 35 with a size matched with that of the condenser tube 28 is formed in each mounting sleeve 34, an annular indicating block 36 is fixedly connected to the condenser tube 28, an indicating groove 37 with a size matched with that of the indicating block 36 is formed in each mounting sleeve 34, the indicating block 36 is abutted against the indicating groove 37, a limiting rod 38 is arranged on each mounting sleeve 34 in a penetrating manner, a limiting groove 39 with a size matched with that of the limiting rod 38 is formed in each indicating block 36, the limiting rod 38 is abutted against the limiting groove 39, a part of the limiting rod 38 extends out of the limiting groove 39, a rotating shaft 40 is hinged to one end of the limiting rod 38 far away from the limiting groove 39, two mounting plates 41 are fixedly connected to the rotating shaft 40, an iron plate 42 is fixedly connected to the mounting plates 41, and a magnetic plate 43 with a size matched with the iron plate 42 is embedded in the end face of each mounting sleeve 34 facing the limiting rod 38, the iron plate 42 and the magnetic plate 43 abut against each other. Therefore, when the condenser tube 28 needs to be disassembled, a worker can separate the magnetic plate 43 from the iron plate 42 by rotating the two mounting plates 41, then pull the limiting rod 38 until the limiting rod 38 is separated from the limiting groove 39, then pull the condenser tube 28 until the indicating block 36 is separated from the indicating groove 37, and then detach the condenser tube 28 from the mounting sleeve 34, so that the worker can repair or replace the condenser tube 28.

The implementation principle of embodiment 2 of the present application is as follows: the closing plate 30 can be detached from the mounting tube 25 by the worker by rotating the connecting bolt 31, then the mounting plate 41 is pulled to separate the magnetic plate 43 and the iron plate 42 from each other, then the limiting rod 38 is pulled to take the limiting rod 38 out of the limiting groove 39, and the plate-pulling condensation tube 28 is detached from the indicating groove 37 until the indicating block 36 is detached, so that the condensation tube 28 can be repaired or replaced by the worker.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a cold and hot integral type temperature machine which characterized in that: including heating circuit (1), cooling circuit (2) and cooling circuit (3), cooling circuit (2) include cold water storage cistern (4), cooling circuit (3) are including intercommunication first branch pipe (5) on compressor (45), the other end and cold water storage cistern (4) of first branch pipe (5) are linked together, and the intercommunication has second branch pipe (6) on compressor (45), second branch pipe (6) communicate in proper order has condenser (7) and expansion pump (8), first branch pipe (5) are linked together with second branch pipe (6), the intercommunication has first condenser pipe (9) that are used for pouring into the cooling water and second condenser pipe (10) that are used for discharging the comdenstion water on condenser (7).

2. The integrated cold and hot water temperature machine as claimed in claim 1, wherein: the heating loop (1) comprises a heater (11), a first circulating pipe (12) is communicated with the heater (11), the first circulating pipe (12) is communicated with a first ball valve (13), a second circulating pipe (14) is communicated with the heater (11), a first circulating pump (15), an exhaust valve (16) and a second ball valve (17) are sequentially communicated with the second circulating pipe (14), the first circulating pipe (12) is communicated with the second circulating pipe (14), a third circulating pipe (18) is communicated between the first circulating pipe (12) and the second circulating pipe (14), one end of the third circulating pipe (18) is arranged at a communication position between the first ball valve (13) and the heater (11), and the other end of the third circulating pipe (18) is arranged at a communication position between the first circulating pump (15) and the exhaust valve (16).

3. The integrated cold and hot water temperature machine as claimed in claim 2, wherein: the cooling water tank (4) is communicated with a first cooling pipe (19), the first cooling pipe (19) is sequentially communicated with a one-way valve (20) and a cooling electromagnetic valve (21), the first cooling pipe (19) is communicated with an exhaust valve (16), the cooling water tank (4) is communicated with a second cooling pipe (22), the second cooling pipe (22) is communicated with a second circulating pump (23), the second cooling pipe (22) is communicated with a second circulating pipe (14), the communication position of the second cooling pipe (22) and the second circulating pipe (14) is communicated with the communication position of the first circulating pump (15) and the exhaust valve (16), a third cooling pipe (24) is communicated between the first cooling pipe (19) and the second cooling pipe (22), one end of the third cooling pipe (24) is communicated with the communication position between the cooling water tank (4) and the one-way valve (20), and the other end of the third cooling pipe (24) is communicated between the second circulating pipe (14) and the cooling electromagnetic valve (21) The communication of (a).

4. The integrated cold and hot water temperature machine as claimed in claim 1, wherein: condenser (7) are including installation pipe (25), inlet port (26) have been seted up on installation pipe (25), venthole (27) have been seted up on installation pipe (25), wear to be equipped with a plurality of condenser pipes (28) on installation pipe (25), condenser pipe (28) part extends to in installation pipe (25), the dismantlement groove (29) have been seted up on installation pipe (25), be equipped with on dismantlement groove (29) and be used for sealing closing closure plate (30) of dismantling groove (29).

5. The integrated cold and hot water temperature machine as claimed in claim 4, wherein: the sealing plate (30) is provided with a plurality of connecting bolts (31) in a penetrating and threaded connection mode, connecting grooves (32) matched with the connecting bolts (31) are formed in the mounting pipe (25), the connecting bolts (31) are connected in the connecting grooves (32) in a threaded mode, the sealing plate (30) is provided with rubber pads (33), and the rubber pads are abutted tightly between the sealing plate (30) and the mounting pipe (25).

6. The integrated cold and hot water temperature machine as claimed in claim 5, wherein: be equipped with a plurality of installation cover (34) on the inner wall of installation pipe (25), seted up on installation cover (34) a plurality of and condenser pipe (28) assorted mounting hole (35), be equipped with on condenser pipe (28) and instruct piece (36), seted up on installation cover (34) and instruct piece (36) assorted instruction groove (37), instruct piece (36) to support tightly in instructing groove (37), wear to be equipped with gag lever post (38) on installation cover (34), instruct to set up on piece (36) with gag lever post (38) assorted spacing groove (39), gag lever post (38) support tightly in spacing groove (39).

7. The integrated cold and hot water temperature machine as claimed in claim 6, wherein: the iron plate fixing device is characterized in that a rotating shaft (40) is rotatably connected to the limiting rod (38), a plurality of mounting plates (41) are arranged on the rotating shaft (40), iron plates (42) are arranged on the mounting plates (41), magnetic plates (43) matched with the iron plates (42) are arranged on the mounting sleeve (34), and the iron plates (42) and the magnetic plates (43) are mutually abutted.

8. The integrated cold and hot water temperature machine as claimed in claim 5, wherein: the connecting groove (32) is provided with a guide groove (44) which is obliquely arranged along the periphery.

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