CN215449093U - Multifunctional zirconia oxygen analysis combination device - Google Patents

Abstract

The utility model provides a multifunctional zirconia oxygen analysis combination device which comprises a shell, an air channel, fermented garbage, an upper side output pipeline, a lower side output pipeline, a discharge filter frame structure, a material residue collection frame structure, an adjustable introduction frame structure, a lower side pipeline, a connecting valve, a gas filter device, a sampling pipeline, a gas flow control valve, a zirconia probe, a heater and a single chip microcomputer control chip, wherein the air channel is arranged at the lower part of the shell. The longitudinal partition net screw is arranged in the middle of the inner side of the mounting outer frame, so that the longitudinal partition net screw is beneficial to conveniently filtering smoke dust entering the mounting outer frame when in use; the storage bottle passes through the adapter sleeve pipe cup joint in the outside lower part of connecting pipe, is favorable to conveniently collecting the storage from the smoke and dust that the hopper of deriving led down when using.

Description

Multifunctional zirconia oxygen analysis combination device

Technical Field

The utility model belongs to the technical field of zirconia oxygen analysis equipment, and particularly relates to a multifunctional zirconia oxygen analysis combination device.

Background

At present, the most common treatment method mainly comprises three methods of landfill, composting and incineration, and in order to achieve the aims of reduction, reclamation and harmlessness of garbage, the composting is combined with a sorting method, and other treatment methods are matched, so that the composting is a promising treatment method.

However, the existing zirconia oxygen analysis combination device has the problems of inconvenience in filtering smoke dust, inconvenience in collecting smoke dust and inconvenience in controlling the air draft direction.

Therefore, it is necessary to invent a multifunctional zirconia oxygen analysis combination device.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides a multifunctional zirconia oxygen analysis combination device, which aims to solve the problems that the existing zirconia oxygen analysis combination device is inconvenient to filter smoke dust, collect smoke dust and control the air draft direction. A multifunctional zirconia oxygen analysis combination device comprises a shell, an air channel, fermented garbage, an upper side output pipeline, a lower side output pipeline, a discharge filter frame structure, a material residue collection frame structure, an adjustable guide frame structure, a lower side pipeline, a connecting valve, a gas filter device, a sampling pipeline, a gas flow control valve, a zirconia probe, a heater and a single chip microcomputer control chip, wherein the air channel is arranged at the lower part of the shell; the fermented garbage is arranged at the upper part of the inner side of the shell; the upper side output pipeline and the lower side output pipeline are respectively inserted in the upper part of the right side of the shell and the middle position of the right side; the discharge filter frame structure is arranged on the right side of the upper output pipeline and the right side of the lower output pipeline; the slag collecting frame structure is arranged at the lower part of the discharging and filtering frame structure; the adjustable leading-in frame structure is arranged at the joint of the lower side pipeline and the lower side output pipeline; the lower side pipeline is inserted in the lower part of the right side of the shell; the connecting valve is in threaded connection with the joint of the lower side pipeline and the gas filtering device; the sampling pipeline is inserted at the lower part of the right side of the gas filtering device; the gas flow control valve is in threaded connection with the middle position of the sampling pipeline; the zirconia probe is connected with a sampling pipeline; the heater and the singlechip control chip are respectively connected with the zirconia probe; the adjustable guide-in frame structure comprises a guide-in frame, a backflow pipeline, a guide-in pipeline, an adjusting valve, a longitudinal mounting rod and an exhaust fan, wherein the guide-in frame is inserted at the right side of the lower side pipeline; the reflux pipeline is inserted at the upper part of the lead-in frame and the lower part of the lower side output pipeline; the lead-in pipeline is inserted at the right side of the lead-in frame; the longitudinal mounting rod is mounted on the inner side of the lead-in frame through a screw; and the exhaust fan screw is arranged on the left side of the longitudinal mounting rod.

Preferably, the discharge filter frame structure comprises an installation outer frame, a left connecting ring, a right connecting ring, a longitudinal separation net and a blower, wherein the left connecting ring is in threaded connection with the right sides of the upper output pipeline and the lower output pipeline; the blower screw is arranged on the right side of the longitudinal separation net.

Preferably, the slag collecting frame structure comprises a guiding hopper, a connecting pipe, a connecting rope, a connecting sleeve and a storage bottle, wherein the connecting pipe is welded at the lower part of the guiding hopper; the connecting sleeve is sleeved outside the connecting pipe; the storage bottle is welded at the lower part of the connecting sleeve.

Preferably, the longitudinal net separating screw is arranged in the middle of the inner side of the mounting outer frame.

Preferably, the storage bottle is sleeved on the lower part of the outer side of the connecting pipe through the connecting sleeve.

Preferably, the regulating valve is respectively screwed at the middle position of the return pipeline and the middle position of the leading-in pipeline.

Preferably, one end of the connecting rope is glued to the right side of the guiding-out bucket, and the other end of the connecting rope is tied to the joint of the connecting sleeve.

Preferably, the left connecting ring and the right connecting ring are respectively welded at the left side and the right side of the mounting outer frame.

Compared with the prior art, the utility model has the beneficial effects that:

1. in the utility model, the longitudinal partition net screw is arranged in the middle of the inner side of the mounting outer frame, which is beneficial to conveniently filtering smoke dust entering the mounting outer frame when in use.

2. In the utility model, the storage bottle is sleeved at the lower part of the outer side of the connecting pipe through the connecting sleeve, so that the storage bottle is beneficial to conveniently collecting and storing smoke dust which is guided downwards from the guide hopper when in use.

3. In the utility model, the regulating valve is respectively in threaded connection with the middle position of the return pipeline and the middle position of the leading-in pipeline, so that the regulating valve on the return pipeline or the leading-in pipeline can be conveniently opened and closed according to the use requirement when in use.

4. In the utility model, one end of the connecting rope is connected to the right side of the guiding-out hopper in an adhesive manner, and the other end of the connecting rope is connected to the joint of the connecting sleeve in an adhesive manner, so that the storage bottle is protected conveniently when in use, and the storage bottle is prevented from falling and losing.

5. In the utility model, the left connecting ring and the right connecting ring are respectively welded at the left side and the right side of the mounting outer frame, so that the left connecting ring or the right connecting ring can be conveniently and threadedly connected with the upper output pipeline or the lower output pipeline when in use.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural view of a drain filter stand structure of the present invention.

FIG. 3 is a schematic structural view of a slag collecting rack structure of the present invention.

Fig. 4 is a schematic structural view of an adjustable lead-in frame structure of the present invention.

In the figure:

1. a housing; 2. an air duct; 3. fermenting the garbage; 4. an upper output duct; 5. a lower output duct; 6. a drain filter frame structure; 61. installing an outer frame; 62. a left connecting ring; 63. a connecting ring on the right side; 64. longitudinal separation nets; 65. a blower; 7. a slag collecting rack structure; 71. A leading-out hopper; 72. a connecting pipe; 73. connecting ropes; 74. connecting a sleeve; 75. a material storage bottle; 8. An adjustable lead-in frame structure; 81. importing a frame; 82. a return line; 83. a lead-in conduit; 84. Adjusting a valve; 85. longitudinally mounting a rod; 86. an exhaust fan; 9. a lower side duct; 10. connecting a valve; 11. a gas filtering device; 12. a sampling pipe; 13. a gas flow control valve; 14. A zirconia probe; 15. a heater; 16. the single chip microcomputer controls the chip.

Detailed Description

The utility model is further described below with reference to the accompanying drawings:

example (b):

as shown in figures 1 and 4

The utility model provides a multifunctional zirconia oxygen analysis combination device, which comprises a shell 1, an air channel 2, fermented garbage 3, an upper side output pipeline 4, a lower side output pipeline 5, a discharge filter frame structure 6, a material slag collection frame structure 7, an adjustable lead-in frame structure 8, a lower side pipeline 9, a connecting valve 10, a gas filter device 11, a sampling pipeline 12, a gas flow control valve 13, a zirconia probe 14, a heater 15 and a single chip microcomputer control chip 16, wherein the air channel 2 is arranged at the lower part of the shell 1; the fermented garbage 3 is arranged at the upper part of the inner side of the shell 1; the upper side output pipeline 4 and the lower side output pipeline 5 are respectively inserted in the upper part of the right side of the shell 1 and the middle position of the right side; the discharge filter frame structure 6 is arranged on the right side of the upper output pipeline 4 and the right side of the lower output pipeline 5; the slag collecting frame structure 7 is arranged at the lower part of the discharging and filtering frame structure 6; the adjustable lead-in frame structure 8 is arranged at the joint of the lower side pipeline 9 and the lower side output pipeline 5; the lower side pipeline 9 is inserted at the lower part of the right side of the shell 1; the connecting valve 10 is in threaded connection with the joint of the lower side pipeline 9 and the gas filtering device 11; the sampling pipeline 12 is inserted at the lower part of the right side of the gas filtering device 11; the gas flow control valve 13 is in threaded connection with the middle position of the sampling pipeline 12; the zirconia probe 14 is connected with the sampling pipeline 12; the heater 15 and the singlechip control chip 16 are respectively connected with the zirconia probe 14; the adjustable guiding frame structure 8 comprises a guiding frame 81, a return pipeline 82, a guiding pipeline 83, a regulating valve 84, a longitudinal mounting rod 85 and an exhaust fan 86, wherein the guiding frame 81 is inserted and connected to the right side of the lower side pipeline 9; the return pipe 82 is inserted in the upper part of the lead-in frame 81 and the lower part of the lower output pipe 5; the leading-in pipeline 83 is inserted at the right side of the leading-in frame 81; the regulating valve 84 is respectively screwed at the middle position of the return pipeline 82 and the middle position of the leading-in pipeline 83, and the regulating valve 84 on the return pipeline 82 or the leading-in pipeline 83 can be conveniently opened and closed according to the use requirement when in use; the longitudinal installation rod 85 is installed on the inner side of the guide-in frame 81 through a screw; the suction fan 86 is mounted on the left side of the longitudinal mounting bar 85 by screws.

As shown in fig. 2, in the above embodiment, specifically, the emission filter frame structure 6 includes an installation outer frame 61, a left connection ring 62, a right connection ring 63, a longitudinal partition net 64 and a blower 65, the left connection ring 62 and the right connection ring 63 are respectively welded on the left and right sides of the installation outer frame 61, and the left connection ring 62 or the right connection ring 63 is used for being in threaded connection with the upper output pipe 4 or the lower output pipe 5; the left connecting ring 62 is in threaded connection with the right sides of the upper output pipeline 4 and the lower output pipeline 5; the longitudinal partition net 64 is arranged at the middle position of the inner side of the mounting outer frame 61 through screws, so that the smoke entering the mounting outer frame 61 can be conveniently filtered when in use; the blower 65 is screwed to the right of the longitudinal screen 64.

As shown in fig. 3, in the above embodiment, specifically, the slag collecting rack structure 7 includes a guiding-out hopper 71, a connecting pipe 72, a connecting rope 73, a connecting sleeve 74 and a storage bottle 75, where the connecting pipe 72 is welded at the lower part of the guiding-out hopper 71; one end of the connecting rope 73 is connected to the right side of the guiding-out hopper 71 in an adhesive manner, and the other end of the connecting rope 73 is connected to the joint of the connecting sleeve 74 in a tying manner, so that the storage bottle 75 is protected conveniently when in use, and the storage bottle 75 is prevented from falling and losing; the connecting sleeve 74 is sleeved outside the connecting pipe 72; the storage bottle 75 is welded at the lower part of the connecting sleeve 74; the storage bottle 75 is sleeved at the lower part of the outer side of the connecting pipe 72 through the connecting sleeve 74, so that the smoke dust guided downwards from the guide hopper 71 can be conveniently collected and stored when the storage bottle is used.

Principle of operation

During operation, when the device is used, air in the upper output pipeline 4 and the lower output pipeline 5 is extracted by the blower 65 according to requirements, then the air is filtered by the longitudinal separation net 64, then filtered waste materials enter the storage bottle 75 through the guide hopper 71 to be stored, then the adjusting valve 84 on the return pipeline 82 or the guide pipeline 83 is opened according to requirements, so that external air is extracted by the exhaust fan 86 and enters the inner side of the air duct 2 through the lower pipeline 9, the connecting valve 10 is opened, the air enters the sampling pipeline 12 through the air filtering device 11, and meanwhile the air flow control valve 13 is controlled to be opened and detected by the zirconia probe 14.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims (8)

1. The multifunctional zirconia oxygen analysis combination device is characterized by comprising a shell (1), an air duct (2), fermented garbage (3), an upper side output pipeline (4), a lower side output pipeline (5), a discharge filter frame structure (6), a material slag collection frame structure (7), an adjustable introduction frame structure (8), a lower side pipeline (9), a connecting valve (10), a gas filtering device (11), a sampling pipeline (12), a gas flow control valve (13), a zirconia probe (14), a heater (15) and a single chip microcomputer control chip (16), wherein the air duct (2) is arranged at the lower part of the shell (1); the fermented garbage (3) is arranged at the upper part of the inner side of the shell (1); the upper side output pipeline (4) and the lower side output pipeline (5) are respectively inserted in the upper part of the right side and the middle position of the right side of the shell (1); the discharge filter frame structure (6) is arranged on the right side of the upper output pipeline (4) and the right side of the lower output pipeline (5); the slag collecting frame structure (7) is arranged at the lower part of the discharging and filtering frame structure (6); the adjustable lead-in frame structure (8) is arranged at the joint of the lower side pipeline (9) and the lower side output pipeline (5); the lower side pipeline (9) is inserted at the lower part of the right side of the shell (1); the connecting valve (10) is in threaded connection with the connecting part of the lower side pipeline (9) and the gas filtering device (11); the sampling pipeline (12) is inserted at the lower part of the right side of the gas filtering device (11); the gas flow control valve (13) is in threaded connection with the middle position of the sampling pipeline (12); the zirconia probe (14) is connected with the sampling pipeline (12); the heater (15) and the single-chip microcomputer control chip (16) are respectively connected with the zirconia probe (14); the adjustable guide frame structure (8) comprises a guide frame (81), a return pipeline (82), a guide pipeline (83), an adjusting valve (84), a longitudinal mounting rod (85) and an exhaust fan (86), wherein the guide frame (81) is inserted and connected to the right side of the lower side pipeline (9); the return pipeline (82) is inserted at the upper part of the lead-in frame (81) and the lower part of the lower side output pipeline (5); the guide-in pipeline (83) is inserted at the right side of the guide-in frame (81); the longitudinal mounting rod (85) is mounted on the inner side of the guide-in frame (81) through a screw; the exhaust fan (86) is installed on the left side of the longitudinal installation rod (85) through a screw.

2. The multifunctional zirconia oxygen analysis assembly of claim 1 wherein said emission filter frame structure (6) comprises an outer mounting frame (61), a left side connection ring (62), a right side connection ring (63), a longitudinal partition net (64) and a blower (65), said left side connection ring (62) is screwed to the right side of the upper side output duct (4) and the lower side output duct (5); the blower (65) is installed on the right side of the longitudinal separation net (64) through screws.

3. The multifunctional zirconia oxygen content analysis combination device according to claim 1, wherein the slag collection frame structure (7) comprises a discharge hopper (71), a connecting pipe (72), a connecting rope (73), a connecting sleeve (74) and a storage bottle (75), wherein the connecting pipe (72) is welded at the lower part of the discharge hopper (71); the connecting sleeve (74) is sleeved outside the connecting pipe (72); the storage bottle (75) is welded at the lower part of the connecting sleeve (74).

4. The multifunctional zirconia oxygen analysis combination according to claim 2, wherein the longitudinal partition net (64) is installed at the middle position of the inner side of the installation frame (61) by screws.

5. The multifunctional zirconia oxygen analysis combination according to claim 3, wherein the storage bottle (75) is sleeved on the lower part of the outer side of the connecting pipe (72) through a connecting sleeve (74).

6. The multifunctional zirconia oxygen analysis assembly according to claim 1, wherein said regulating valve (84) is screwed to an intermediate position of the return line (82) and an intermediate position of the introduction line (83), respectively.

7. The multifunctional zirconia oxygen content analysis combination according to claim 3, wherein one end of the connecting rope (73) is glued to the right side of the guiding hopper (71), and the other end of the connecting rope (73) is tied to the joint of the connecting sleeve (74).

8. The multifunctional zirconia oxygen analysis assembly according to claim 2, wherein said left connecting ring (62) and said right connecting ring (63) are welded to the left and right sides of the mounting frame (61), respectively.

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