CN219841735U - Forced air drying pipeline system - Google Patents

Abstract

The utility model relates to the technical field of forced air drying equipment, in particular to a forced air drying pipeline system which comprises an air amplifier, wherein an air inlet of the air amplifier is communicated with an air source pipe, a circulating pipe is communicated between a drainage port of the air amplifier and a drying cabinet, an air inlet pipe is communicated between an ejection port of the air amplifier and the drying cabinet, and the forced air drying pipeline system further comprises an exhaust pipe, and the exhaust pipe is communicated with the drying cabinet. The air amplifier is adopted to blow, the traditional fan is abandoned, the air amplifier is small in size and small in occupied space, no matter whether the air amplifier is built-in or built-out, excessive space cannot be occupied, the equipment size can be effectively controlled, and the equipment cost is reduced.

Description

Forced air drying pipeline system

Technical Field

The utility model relates to the technical field of forced air drying equipment, in particular to a forced air drying pipeline system.

Background

The medical apparatus must be dried after cleaning, and one of the common drying modes at present is to put the apparatus into a blast drying cabinet for heating and blasting at the same time to realize drying.

The current forced air drying cabinet generally adopts the combination of motor, fan and wind channel, and the fan embeds in working chamber, drives the fan through the motor and rotates, drives the wind and flows, circulate fast in working chamber, realizes the drying of medical instrument. In the design, the air duct and the fan occupy the space of the working chamber, so that a larger space cannot be utilized, and space waste is caused; if the same effective working space is to be ensured, the working chamber size and the product outline size are to be increased, and the processing cost is to be increased. During actual production, the fan is also considered to be arranged outside the working chamber, at the moment, high-temperature and high-humidity gas in the working chamber needs to be led out through a pipeline and blown back to the working chamber by the fan to realize circulation, but the fan cannot bear the corrosion of the high-temperature and high-humidity gas, so that the fan cannot be arranged outside the working chamber in a circulating way.

Disclosure of Invention

The utility model aims to provide a forced air drying pipeline system which is applied to a forced air drying cabinet to solve the problem that the existing forced air drying cabinet wastes space.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a forced air drying pipe system, includes air amplifier, and air amplifier's air inlet intercommunication has the air supply pipe, communicates the circulating pipe between air amplifier's drainage mouth and the drying cabinet, and air amplifier's the port of spouting communicates between and the drying cabinet has the intake pipe, still includes the blast pipe, and the blast pipe communicates on the drying cabinet.

The principle of the scheme is as follows:

the air source pipe is used for being externally connected with a working air source, compressed air enters the air amplifier through the air source pipe, the compressed air is used as a power source, the air in the drying cabinet is pulled into the air amplifier through the circulating pipe, and the air is converged into high-pressure and high-speed air flow and then enters the drying cabinet through the air inlet pipe; most of the gas in the cabinet is returned to the air amplifier through the circulating pipe, and the small part of the gas is discharged through the exhaust pipe, so that the gas is circulated, the air pressure balance in the drying cabinet is kept, and the forced air drying is realized.

The beneficial effect of this scheme is:

1. the air amplifier is adopted to blow, the traditional fan is abandoned, the air amplifier is small in size and small in occupied space, no matter whether the air amplifier is built-in or built-out, excessive space cannot be occupied, the equipment size can be effectively controlled, and the equipment cost is reduced.

2. According to the scheme, the air amplifier is arranged externally, compared with the built-in air amplifier, the air amplifier does not occupy the working space inside the drying cabinet, the equipment volume is not increased, and the equipment cost is effectively controlled.

3. The air amplifier is adopted, and only a small amount of compressed air is used as an air source to realize large air quantity flow, so that the energy consumption is reduced, and the resources are saved.

4. The air amplifier can withstand high-temperature and high-humidity gas, so that the air circulation can be smoothly performed by adopting an external device.

Further, a heating pipe is communicated between the air amplifier and the air inlet pipe.

The beneficial effects are that: the heating element is taken from in the current drying cabinet, and this scheme adds between air amplifier and intake pipe establishes the heating pipe, can heat the gas of blowing into the drying cabinet in advance, and the blowing is hot-blast promptly, and drying effect is good.

Further, the air inlet pipe is communicated with the bottom of the drying cabinet, and the circulating pipe is communicated with the top of the drying cabinet.

The beneficial effects are that: because the steam has the performance of come-up, so set up the intake pipe at drying cabinet bottom and be favorable to the steam of drum to be full of the drying cabinet more fast, the circulation pipe setting is then favorable to leading out high temperature high humidity gas and circulate at drying cabinet top in the same way.

Further, the air source pipe is communicated with a detection piece for detecting whether an air source exists in the air source pipe.

The beneficial effects are that: the arrangement can ensure that a compressed air source enters the air amplifier, ensures the normal operation of the system and is convenient to overhaul.

Further, a valve is arranged on the air source pipe.

The beneficial effects are that: the valve is used for controlling the on-off of the air source, and the valve is additionally arranged on the air source pipe, so that compared with the control of a switch of the air source equipment, the control of the valve on the air source pipe is more convenient.

Further, the valve adopts an electromagnetic valve.

The beneficial effects are that: the electromagnetic valve is simple in structure and convenient to operate and control.

Further, the heating pipe and the air inlet pipe are coated with heat insulation layers.

The beneficial effects are that: the heat loss can be reduced by arranging the heat preservation layer, and the heating pipe and the air inlet pipe can be protected.

Further, the air amplifier is detachably connected with the circulating pipe, the heating pipe and the air source pipe.

The beneficial effects are that: by adopting the scheme, each part is convenient to disassemble, assemble and replace.

Further, a butterfly valve is mounted on the exhaust pipe.

The beneficial effects are that: when high-pressure high-speed gas is blown into the drying cabinet, the air pressure in the drying cabinet is increased, the butterfly valve is pressed open, partial gas is automatically discharged from the exhaust pipe, and the butterfly valve is arranged to realize automatic exhaust, so that the drying cabinet can be prevented from being in a high-pressure state for a long time, and the risk of high-pressure explosion is avoided.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model.

Detailed Description

The following is a further detailed description of the embodiments:

reference numerals in the drawings of the specification include: the air source connector 1, the tee joint 2, the detecting piece 3, the air source pipe 4, the electromagnetic valve 5, the drainage port 6, the air amplifier 7, the air inlet 8, the ejection port 9, the heating pipe 10, the air inlet pipe 11, the circulating pipe 12, the exhaust pipe 13, the drying cabinet 14, the exhaust pipe 15 and the butterfly valve 16.

An example is substantially as shown in figure 1:

the blast drying pipeline system comprises an air amplifier 7, a heating pipe 10, an air inlet pipe 11, a circulating pipe 12 and an exhaust pipe 13, wherein the exhaust pipe 13 is communicated with the top of a drying cabinet 14, an exhaust pipe 15 is communicated with the exhaust pipe, and a butterfly valve 16 is arranged in the exhaust pipe 15. In this embodiment, the air amplifier 7 adopts the existing air amplifier 7, the inlet for inputting compressed air is the air inlet 8, the inlet for driving ambient air into is the drainage port 6, and the outlet for exhausting air is the ejection port 9, and the structure is the prior art and will not be described here. The air inlet 8 of the air amplifier 7 is communicated with an air source pipe 4 through a quick-plug external thread right-angle joint, an electromagnetic valve 5 is arranged on the air source pipe 4, a tee joint 2 is further communicated with the air source pipe 4, one end of the tee joint 2 is communicated with an air source joint 1 for externally connecting an air source, such as a compressed air source interface of a hospital, the other end of the tee joint 2 is communicated with a detection part 3 for detecting whether an air source exists in the air source pipe 4, and in the embodiment, the detection part 3 adopts an sns diaphragm type adjustable pressure switch.

The circulating pipe 12 is communicated between the drainage port 6 of the air amplifier 7 and the top of the drying cabinet 14, the exhaust port 9 of the air amplifier 7 is communicated with the heating pipe 10, the air inlet pipe 11 is communicated between the heating pipe 10 and the bottom of the drying cabinet 14, and the air amplifier 7 is detachably connected with the circulating pipe 12, the heating pipe 10 and the air source pipe 4, for example, through a pipe hoop. The heating pipe 10 and the air inlet pipe 11 are coated with heat preservation layers, and the heat preservation layers adopt heat preservation sponge.

The specific implementation process is as follows:

the air source pipe 4 is externally connected with a compressed air source, the electromagnetic valve 5 is opened, the compressed air is introduced into the air amplifier 7, the compressed air is used as a power source to drive ambient air to flow to the amplifier, namely, the air in the drying cabinet 14 is pulled into the air amplifier 7 through the circulating pipe 12 to form high-pressure and high-speed air flow which is sprayed out from the spraying port 9, and the high-pressure and high-speed air flow enters the drying cabinet 14 through the air inlet pipe 11 after being heated by the heating pipe 10. Most of the gas in the drying cabinet 14 is led out to the air amplifier 7 for circulation through the circulating pipe 12, and a small part of the gas is directly discharged from the exhaust pipe 13 (when the gas is blown in, the air pressure in the drying cabinet 14 is increased, the butterfly valve 16 is pressed open, and the exhaust pipe 13 can exhaust), so that the forced air circulation drying of the drying cabinet 14 is realized repeatedly.

The embodiment adopts the air amplifier 7 to blow, compares and adopts the fan, and the air amplifier 7 is small, and neither built-in or external can occupy too much space, and the air amplifier 7 can bear the high temperature high humidity gas that drying cabinet 14 internal circulation comes out, therefore this scheme is external with the air amplifier 7 outside the inner bag of drying cabinet 14, the effectual problem that adopts the fan can only built-in, and lead to the space extravagant has been guaranteed the effectual working space of drying cabinet 14, avoided increasing equipment volume, the effectual equipment cost of having controlled. In addition, the embodiment utilizes the characteristic of amplifying the gas by the air amplifier 7, abandons the traditional blower blowing mode, can achieve the purpose of large air volume flow by using a small amount of compressed gas, and saves resources.

The foregoing is merely exemplary embodiments of the present utility model, and specific structures and features that are well known in the art are not described in detail herein. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the structure of the present utility model, and these should also be considered as the scope of the present utility model, which does not affect the effect of the implementation of the present utility model and the utility of the patent. The protection scope of the present utility model is subject to the content of the claims, and the description of the specific embodiments and the like in the specification can be used for explaining the content of the claims.

Claims (9)

1. An air blast drying pipeline system, characterized in that: the air source tube is communicated with an air inlet of the air amplifier, a circulating tube is communicated between a drainage port of the air amplifier and the drying cabinet, an air inlet tube is communicated between an ejection port of the air amplifier and the drying cabinet, and the air source tube further comprises an exhaust tube which is communicated with the drying cabinet.

2. A forced air drying duct system according to claim 1, wherein: a heating pipe is communicated between the air amplifier and the air inlet pipe.

3. A forced air drying duct system according to claim 2, wherein: the air inlet pipe is communicated with the bottom of the drying cabinet, and the circulating pipe is communicated with the top of the drying cabinet.

4. A forced air drying duct system according to claim 1, wherein: the air source pipe is communicated with a detection piece for detecting whether an air source exists in the air source pipe.

5. A forced air drying duct system according to any one of claims 1-4, wherein: the air source pipe is provided with a valve.

6. A forced air drying duct system according to claim 5, wherein: the valve adopts an electromagnetic valve.

7. A forced air drying duct system according to claim 6, wherein: the heating pipe and the air inlet pipe are coated with heat insulation layers.

8. A forced air drying duct system according to claim 7, wherein: the air amplifier is detachably connected with the circulating pipe, the heating pipe and the air source pipe.

9. A forced air drying duct system according to claim 1, wherein: the butterfly valve is arranged on the exhaust pipe.