CN214065514U - Airflow drying equipment for laboratory glass instrument - Google Patents

Abstract

The utility model discloses an air current drying equipment for laboratory glass instrument, including the equipment principal, equipment principal upper surface is equipped with a plurality of inside cavities, is used for hanging the tuber pipe of glass instrument that have, and each tuber pipe all is equipped with a plurality of air outlets, and the equipment principal still is equipped with the mass flow device, outside in order to prevent to flow to the equipment principal from the liquid of flowing in the glass instrument. When the glass instrument is used, the glass instrument is inversely hung on the air pipe, and the water on the inner wall of the vessel is collected and flows out under the action of gravity and flows into the flow collecting device, so that the liquid can be prevented from splashing or dripping onto a laboratory desktop or the ground. Because the following current of water with collect water, remaining a small amount of water can volatilize relatively fast under the effect of airflow drying equipment in the household utensils, realizes that the household utensils dry fast, reduces equipment consumption, the energy saving, simple and practical, the household utensils are invertd upright moreover, has reduced occupation space greatly, can increase household utensils stoving quantity, still can suitably reduce equipment volume, does not occupy operating space, make full use of laboratory space.

Description

Airflow drying equipment for laboratory glass instrument

Technical Field

The utility model relates to a laboratory paraphernalia technical field, more specifically say, relate to an air current drying equipment for laboratory glass instrument.

Background

At present, the common household utensils are dried mainly in an electric heating mode, and pre-control water treatment is required before the household utensils are dried. The common ware drying equipment is an electric heating air blast drying box, and the suitable objects are glass products such as glass test tubes, glass triangular flasks, glass beakers, viscometer and the like.

The applicant has found that the prior art has at least the following technical problems: when the electrothermal blowing drying oven is used for drying the Hill viscometer, the Hill viscometer is directly and flatly placed on a shelf, but because the pipe diameter of the Hill viscometer is small, moisture accumulated in the deep part of the Hill viscometer is difficult to discharge, the moisture volatilization is slow, the drying efficiency is low, and the energy consumption of equipment is high. And the number of utensils that can dry once in the case is limited, and other utensils of waiting to dry need in time to collect to change after the household utensils are dried.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an air current drying equipment for laboratory glass instrument to compensate not enough among the prior art, have advantages such as quick energy-conservation, convenient to use, improve drying efficiency, reduce energy consumption.

The utility model aims at realizing through the following technical scheme:

the utility model provides a pair of air current drying equipment for laboratory glass instrument, including the equipment principal, the upper surface of equipment principal is equipped with a plurality of inside cavities, is used for hanging the tuber pipe of glass instrument, each the tuber pipe all is equipped with a plurality of air outlets, the equipment principal still is equipped with the mass flow device that is used for collecting the liquid that flows in the glass instrument, flows to in order to prevent from the interior liquid flow that flows of glass instrument the equipment principal is external.

Preferably, the collecting device comprises an annular protruding structure arranged along the circumference of the device body, and the annular protruding structure is provided with a collecting groove for collecting liquid.

Preferably, each air pipe is obliquely arranged, and an included angle between each air pipe and the horizontal plane is 60-90 degrees.

Preferably, the top end of each air pipe is provided with an anti-damage glue head.

Preferably, the breakage-proof rubber head is a rubber head or a silicon head.

Preferably, each of the air ducts is uniformly distributed on the upper surface of the apparatus body in a matrix form.

Preferably, the air outlets are uniformly distributed on the air pipe, and the number of the air outlets is 12-30.

Preferably, each air pipe is cylindrical, the outer diameter of each air pipe is 8 mm-17 mm, and the length of each air pipe is 160 mm-200 mm.

Preferably, the device body comprises a cylindrical shell, the shell is made of plastic or stainless steel, the outer diameter of the shell is 380 mm-420 mm, and the height of the shell is 420 mm-460 mm.

Preferably, the upper surface of the housing is a circular arc surface.

The utility model provides an among the technical scheme, an air current drying equipment for laboratory glass instrument includes the equipment main part, and the upper surface of equipment main part is equipped with a plurality of inside and has the cavity, is used for hanging the tuber pipe of glass instrument, and each tuber pipe all is equipped with a plurality of air outlets, and the equipment main part still is equipped with the mass flow device that is used for collecting the liquid that flows in the glass instrument, outside the liquid flow to the equipment main part that flows in order to prevent from the glass instrument. So set up, invert the glassware during use and hang on the tuber pipe, the moisture of household utensils inner wall collects the outflow under the action of gravity, flows to the mass flow device in, can avoid liquid to splash or drip laboratory desktop or subaerial. Because the following current of water with collect water, remaining a small amount of water can volatilize relatively fast under the effect of airflow drying equipment in the household utensils, realizes that the household utensils dries fast, reduces the electric energy of equipment consumption, the energy saving, simple and practical, the household utensils are invertd upright on the tuber pipe in addition, has reduced occupation space greatly, can increase household utensils stoving quantity, still can suitably reduce equipment volume, does not occupy operating space, make full use of laboratory space.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is the embodiment of the present invention provides a schematic structural diagram of an airflow drying device for laboratory glassware.

In fig. 1:

1-a device body; 2-air pipe; 3, air outlet; 4-a ring-shaped convex structure; 5-a collecting groove; 6-breakage-proof rubber head.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be described in detail below. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. The embodiments described below do not limit the scope of the invention described in the claims. Further, the entire contents of the configurations shown in the following embodiments are not limited to those necessary as a solution of the invention described in the claims.

It should be noted that, in terms of the arrangement position of the airflow drying device for laboratory glassware shown in fig. 1, the vertical direction in the drawing is the pointed vertical direction and the height direction.

Referring to fig. 1, the airflow drying apparatus for laboratory glass instruments provided in this embodiment includes an apparatus main body 1, a plurality of air pipes 2 having cavities therein and used for suspending glass instruments are disposed on an upper surface of the apparatus main body 1, and the air pipes 2 may be fixedly connected to the apparatus main body 1 through mounting seats. Each tuber pipe 2 all is equipped with a plurality of air outlets 3 to supply gas to blow out through air outlet 3 in the tuber pipe 2, come dry household utensils inner wall. The device body 1 is also provided with a current collecting device for collecting the liquid flowing out of the glass instrument so as to prevent the liquid flowing out of the glass instrument from flowing out of the device body 1 and ensure the safe use of the electric appliance. So set up, invert the glassware during use and hang on the tuber pipe, the moisture of household utensils inner wall collects the outflow under the action of gravity, flows to the mass flow device in, can avoid liquid to splash or drip laboratory desktop or subaerial. Because the following current of water with collect water, the water that remains in a small amount and is not collected in the household utensils can volatilize relatively fast under the air current stoving effect, realizes that the household utensils dry fast, reduces the electric energy of equipment consumption, the energy saving, simple and practical, and the household utensils are invertd upright on the tuber pipe in addition, have reduced occupation space greatly, can increase household utensils stoving quantity, still can suitably reduce equipment volume, do not occupy operating space, make full use of laboratory space.

As shown in fig. 1, the collecting device comprises a ring-shaped protruding structure 4 arranged along the circumference of the device body 1, the ring-shaped protruding structure 4 is provided with a collecting groove 5 for collecting liquid, and the size of the collecting groove 5 can be determined according to actual use conditions. Thus, when the liquid flows down, the liquid is collected in the collecting groove 5, and the liquid flowing out of the vessel in an inverted mode can be completely received. In addition, the annular protruding structure 4 can also be used as a lifting lug, so that the laboratory staff can carry the mobile equipment conveniently.

In this embodiment, each air duct 2 is disposed obliquely, and the included angle between each air duct 2 and the horizontal plane is 60 degrees to 90 degrees, preferably 75 degrees, such an angle can facilitate stably suspending the vessel. As shown in fig. 1, a plane perpendicular to the paper surface in the left-right direction is a horizontal plane.

Because the household utensils in the laboratory are glassware mostly, in order to prevent that the household utensils from damaging, consequently in the embodiment of the utility model discloses a 2 tops of each tuber pipe all are equipped with breakage-proof rubber head 6. Preferably, the breakage-proof rubber head 6 is a rubber head or a silicon head, the top end of the air pipe 2 is sleeved with the breakage-proof rubber head, the bottom of a vessel can be protected when the vessel is placed, and the vessel is prevented from being broken and damaged by the aid of elastic performance of the breakage-proof rubber head 6. Of course, the material of the breakage-proof rubber head 6 is not limited to this, and may be other materials to meet the use requirements.

In order to make full use of the laboratory space, as an alternative embodiment, the respective air ducts 2 are uniformly distributed on the upper surface of the apparatus body 1 in a matrix form. Therefore, the airflow drying equipment can be used for simultaneously suspending and placing a plurality of utensils, the space is fully utilized, and the resource waste is reduced.

In the present embodiment, the air outlets 3 are evenly distributed on the air duct 2, so that the inner wall of the vessel is evenly dried everywhere. The number of the air outlets 3 is 12-30, for example, during actual processing, the air duct can be divided into three types, and the number of the air outlets 3 corresponding to each type is 12, 20, and 30, so as to meet the requirements of different customers.

As shown in fig. 1, each air duct 2 is cylindrical, and the outer diameter of each air duct 2 is 8 mm-17 mm, and the length of each air duct 2 is 160 mm-200 mm. Specifically, the air duct 2 can be divided into three specifications, i.e., a thick specification, a medium specification and a thin specification, the lengths of the specifications are different, and the outer diameter/length of the air duct 2 corresponding to each specification is 17 mm/200 mm, 12 mm/180 mm and 8 mm/160 mm, so as to meet the use requirements of different vessels. Especially the plat's viscometer, the pipe diameter of the air pipe 2 is small, which is beneficial to the reliable inverted suspension of the plat's viscometer. In other embodiments, the drying device can be made into a standard pipe or a special pipe and the like for drying glassware with different specifications and shapes.

As an optional implementation mode, the device main body 1 comprises a cylindrical shell, the shell is made of plastic or stainless steel, and can be divided into B, C series, and the B series drying device is made of a plastic shell and processed by adopting a thin plate plastic spraying process; the C series drying equipment is a stainless steel shell and is formed by processing a stainless steel plate, the thickness of the C series drying equipment is not limited, and the C series drying equipment can be designed in size according to actual demand conditions. Each series can form various products according to the air pipes 2 with different specifications, the air outlets 3 with different numbers and the like, so that the users can select the products. The outer diameter of the housing is 380 mm to 420 mm, preferably 400 mm. The height of the shell is 420 mm-460 mm, preferably 440 mm. The equipment volume is less relatively like this, can reduce the space and occupy simple and practical.

In the preferred scheme of this embodiment, the upper surface of casing is the arc surface, so on the one hand can increase the arrangement space of tuber pipe, does benefit to the household utensils drying, and on the other hand also does benefit to the moisture and flows to the periphery, finally collects in the collection groove of edge. In addition, the bottom of the shell is provided with feet, and the shell is internally provided with an air flow pump for pumping air into the pipeline, a heating device for heating the air and a temperature controller for controlling the heating temperature of the air. When the drying device works, air enters a pipeline inside the shell from the air inlet through the airflow pump, then passes through the heating device, and the heated air is led into the cavities in the air pipes 2 and finally blown to the inner wall of the vessel from the air outlets 3 to be dried. Meanwhile, the gas heating temperature can be automatically controlled by the temperature controller, if the adjustable temperature range is 40-120 ℃, the gas heating temperature can not be influenced by the ambient temperature, the gas heating temperature is not overheated in summer, the gas heating temperature is still quick and efficient in winter, different use requirements can be met, and the gas heating temperature can also be used for some special purposes needing low-temperature drying. As shown in fig. 1, the housing may be provided with corresponding operation buttons for user operation. The upper part in the middle of the shell is provided with a knob for adjusting the air outlet speed of the airflow pump, and the knob can be divided into three gears, namely a high gear, a low gear, a middle gear and a low gear, and the three gears correspond to airflow temperatures in different intervals respectively. The lower part of the left end of the shell is provided with a knob for adjusting cold air and hot air and an indicator light corresponding to the knob, when the hot air gear is turned, the indicator light is on, and when the cold air gear is turned, the indicator light is off; the cold air refers to an interval with relatively low air heating temperature, and the hot air refers to an interval with relatively high air heating temperature. The lower part of the right end of the shell is provided with a power switch and an indicator light corresponding to the power switch, and the indicator light is turned on when the switch is turned on. The fuse is also arranged in the middle of the two indicator lamps to play a role of overload protection, and when the heating temperature is too high and abnormal, the fuse can melt and cut off current, so that the safety operation of the circuit is protected. It should be noted that the above-mentioned airflow pump, heating device, temperature controller, operation button and related control logic designs are the existing mature technologies, and therefore the specific structure and connection relationship thereof are not described herein again.

The embodiment provides airflow drying equipment for laboratory glass instruments, compared with the prior art, the equipment is small in size, can be combined with the laboratory condition, does not occupy effective operation space, and fully utilizes the laboratory space if directly placed on a laboratory bench; and the tuber pipe slope upwards sets up, and the inversion that the household utensils can be stable during the use hangs on the tuber pipe, and household utensils inner wall moisture collects the outflow under the action of gravity, can avoid liquid to splash on flowing to the mass flow groove. The equipment consumes less electric energy and saves energy; because the following current of water with collect water, a small amount of water that does not collect in the household utensils can be dried more fast, simple and practical has advantages such as quick energy-conservation, no water stain, installation convenient to use, maintenance are simple.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The airflow drying equipment for the laboratory glass instrument is characterized by comprising an equipment body (1), wherein a plurality of air pipes (2) which are internally provided with cavities and used for hanging the glass instrument are arranged on the upper surface of the equipment body (1), each air pipe (2) is provided with a plurality of air outlets (3), and the equipment body (1) is further provided with a flow collecting device used for collecting liquid flowing out of the glass instrument so as to prevent the liquid flowing out of the glass instrument from flowing out of the equipment body (1).

2. The air flow drying apparatus for laboratory glassware according to claim 1, characterized in that said collecting device comprises an annular projecting structure (4) arranged circumferentially along said apparatus body (1), said annular projecting structure (4) being provided with a collecting channel (5) for collecting liquid.

3. The air flow drying apparatus for laboratory glass instruments according to claim 1, wherein each of said air ducts (2) is disposed obliquely, and an angle between each of said air ducts (2) and a horizontal plane is 60-90 degrees.

4. The air flow drying apparatus for laboratory glass instruments according to claim 1, wherein the top end of each of said air pipes (2) is provided with a breakage-proof glue head (6).

5. The air flow drying apparatus for laboratory glass instruments according to claim 4, characterized in that the breakage-proof rubber head (6) is a rubber head or a silicone head.

6. The air flow drying apparatus for laboratory glass instruments according to claim 1, wherein each of the air ducts (2) is uniformly distributed on the upper surface of the apparatus body (1) in a matrix form.

7. The air flow drying apparatus for laboratory glass apparatuses according to claim 1, wherein each of said air outlets (3) is uniformly distributed on said air duct (2), the number of said air outlets (3) being 12-30.

8. The air flow drying apparatus for laboratory glass instruments according to claim 1, wherein each of the air ducts (2) is cylindrical, and each of the air ducts (2) has an outer diameter of 8 mm to 17 mm, and each of the air ducts (2) has a length of 160 mm to 200 mm.

9. The air flow drying apparatus for laboratory glass instruments according to claim 1, characterized in that the apparatus body (1) comprises a cylindrical housing made of plastic or stainless steel, the housing having an outer diameter of 380 mm to 420 mm and a height of 420 mm to 460 mm.

10. The airflow drying apparatus for laboratory glassware according to claim 9, wherein the upper surface of said housing is a circular arc.

Images