CN110585980A - Mixing device - Google Patents

Abstract

The invention is suitable for the technical field of reagent mixing and provides a mixing device. The mixing device provided by the invention comprises a body, a compressed gas input pipe and a mixing output piece. The body is internally provided with a containing cavity for containing at least two reagents; the compressed gas input pipe is connected with the body and used for inputting compressed gas into the accommodating cavity; the mixing output part comprises a mixing pipe and at least two access pipes, wherein one end of each access pipe is contacted with at least one reagent in the accommodating cavity, and the other end of each access pipe is communicated with the mixing pipe; the mixing tube mixes the reagents flowing in from each access tube and outputs the mixed reagents. Through the setting, different reagents can get into different access pipes under compressed gas's effect, finally mix in the hybrid tube, realize instant mixing output to promote the speed that reagent mixes, improved mixing arrangement's production efficiency.

Description

Mixing device

Technical Field

The invention belongs to the technical field of reagent mixing, and particularly relates to a mixing device.

Background

In forging production, a lubricant is required to be sprayed on the working surfaces of the upper die and the lower die, and the common lubricant is A, B mixture of two reagents, so that the two reagents are required to be mixed and then sprayed out. However, the mixing device requires a sufficient mixing time for mixing the two reagents to be uniform, and thus mixing and ejection of the reagents cannot be performed quickly.

Disclosure of Invention

In view of this, the embodiment of the present invention provides a mixing device to solve the technical problem that the mixing device cannot rapidly and uniformly mix a plurality of reagents.

In order to solve the above problems, the technical solution of the embodiment of the present invention is implemented as follows: the mixing device of the present invention comprises: the device comprises a body, a first reagent box and a second reagent box, wherein a containing cavity for containing at least two reagents is formed inside the body; the compressed gas input pipe is connected with the body and used for inputting compressed gas into the accommodating cavity; the mixing output part comprises a mixing pipe and at least two access pipes; one end of each access pipe is in contact with at least one reagent in the containing cavity, and the other end of each access pipe is communicated with the mixing pipe; the mixing pipe mixes the at least two reagents flowing in from the access pipe and outputs the mixed reagents.

Further, the mixing device further comprises: the separator is arranged in the accommodating cavity and divides the accommodating cavity into at least two sub-cavities, and each sub-cavity is used for accommodating one reagent.

Further, the partition is detachably connected with the body.

Further, different ones of the access tubes are in contact with different ones of the agents within the sub-chambers.

Further, the body includes: the upper end of the cavity is opened and is used for forming the accommodating cavity; the cover body is used for sealing the opening of the cavity; wherein the compressed gas input tube and the mixing output member penetrate the cover body.

Further, the mixing device further comprises: the stirring piece penetrates through the cover body and extends into the accommodating cavity, and is used for stirring the at least two reagents; the stirring piece is fixedly connected with the cover body.

Further, the body further comprises: and the power device is used for being connected with the stirring piece to drive the stirring piece to rotate.

Further, the mixing device further comprises: and the reagent input device is connected with the body and is used for inputting the at least two reagents into the accommodating cavity.

Further, the reagent input device comprises a plurality of sub-devices, each sub-device is used for inputting one reagent into the containing cavity, and the reagent input by different sub-devices is different.

Further, at least one of the reagent input, the compressed gas input and the mixing output is provided with a flow control device.

The mixing device provided by the embodiment of the invention is provided with the mixing output part, and the mixing output part comprises a mixing pipe and at least two access pipes, wherein one end of each access pipe is contacted with at least one reagent in the accommodating cavity, the other end of each access pipe is communicated with the mixing pipe, and the mixing pipe is used for mixing and outputting the reagent flowing in from each access pipe. Thereby, different reagents can get into different access pipes under compressed gas's effect, finally mix in the hybrid tube, realize instant mixing output to promote the speed that reagent mixes, improved mixing arrangement's production efficiency.

Drawings

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

FIG. 1 is a front view (without partition) of a mixing device according to an embodiment of the present invention;

FIG. 2 is a front view (with baffles) of a mixing device according to an embodiment of the present invention;

fig. 3 is a side view of a mixing device provided by an embodiment of the present invention.

Description of reference numerals:

11-a mixing device; 111-a body; 1111-a containing cavity; 1112-a cover; 1113-power plant; 1114-pressure gauge; 112-compressed gas input pipe; 113-a mixing output; 1131-mixing tube; 1132 — an access tube; 114-a separator; 115-a stirring member; 116-a reagent input device; 117-flow control means.

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.

The individual features described in the embodiments can be combined in any suitable manner without departing from the scope, for example different embodiments and aspects can be formed by combining different features. In order to avoid unnecessary repetition, various possible combinations of the specific features of the invention will not be described further.

As shown in fig. 1, a mixing device 11 according to an embodiment of the present invention includes a body 111, a compressed gas input pipe 112, and a mixing output member 113. The mixing device 11 may be used to mix a plurality of liquid reagents, and output different reagents after mixing in the body 111 and/or the mixing output member 113. The reagent of the present invention is in a liquid form, and the components and the application fields thereof are not limited, and specifically, the reagent may be a lubricant, a paint, an alcohol, a beverage, or the like. According to different specific liquid components, the mixing device 11 provided by the invention can be applied to a plurality of fields such as chemical industry, industrial manufacturing, catering and the like, and is used for mixing and outputting reagents with different components. It will be appreciated by those skilled in the art that the composition of the reagents and the field of application are not limiting of the mixing device itself, and that the following description will be given by way of example of the field of mixing and spraying of lubricants used in hub forging with the mixing device.

The body 111 is formed therein with receiving chambers 1111 for receiving different reagents. Specifically, the containing cavity 1111 is an integrated cavity, and at least two different kinds of reagents are directly mixed in the cavity; alternatively, the accommodating chamber 1111 has sub-chambers isolated from each other, and different sub-chambers may accommodate different reagents, or a plurality of sub-chambers may accommodate the same reagent, as long as the accommodating chamber accommodates two or more reagents in total. In the use, the space of holding chamber 1111 is divided into holds reagent part and holds gaseous part, and the proportion that two parts account for holding chamber 1111 can be adjusted according to actual demand, holds gaseous part and is located the top that holds reagent part.

The compressed gas input pipe 112 is connected to the body 111, and is communicated with the receiving chamber 1111 formed inside the body 111, for inputting compressed gas into the receiving chamber 1111. Specifically, the compressed gas input pipe 112 may be provided in plurality, and all communicate with the containing cavity 1111, and keep a certain distance from the liquid level of the reagent in the containing cavity 1111, and input the compressed gas into the containing cavity 1111 through the compressed gas input pipe, increase the pressure in the containing cavity 1111, and then press the reagent in the containing cavity 1111 to enter the mixing output member 113 to be mixed and output. The compressed gas may be carbon dioxide, nitrogen, argon, or other gaseous substances.

A mixing output 113 comprising a mixing tube 1131 and at least two access tubes 1132; specifically, one end of each access tube 1132 is in contact with at least one reagent in the containing cavity 1111, and the other end is communicated with the mixing tube 1131; the mixing pipe 1131 mixes at least two reagents flowing in the access pipe 1132 and outputs the mixed reagents. For example, in the case where the receiving chamber 1111 is a single integral chamber, mixing of at least two reagents has been performed in the receiving chamber, the components of the reagents introduced into each of the introduction tubes 1132 include at least two reagents, and then all of the introduction tubes are connected to one end of the mixing tube 1131, and in the mixing tube 1131, at least two reagents introduced from the respective introduction tubes 1132 are mixed again and then ejected from the outlet at the other end of the mixing tube 1131. Also can be under the condition that holds chamber 1111 and divide into a plurality of sub-chambers, each inserts pipe 1132 and contacts with the reagent in its sub-chamber that corresponds, for example, hold chamber 1111 and divide into two sub-chambers, two sub-chambers hold different reagent A and reagent B respectively, two insert pipes 1132 and insert a sub-chamber respectively this moment, correspond and contact with A reagent or B reagent, these two reagents do not mix in holding chamber 1111, but just mix when the rethread inserts pipe 1132 enters into mixing tube 1131, and then spout from mixing tube 1131's export. Alternatively, the mixing tube 1131 of the mixing output 113 may be provided with a length that is only capable of meeting the mixing requirements of different reagents from different access tubes 1132.

Through the above arrangement, the compressed gas passing through the compressed gas input pipe 112 enters the gas containing part of the containing cavity 1111 formed inside the body 111, the pressure in the containing cavity 1111 is increased, the reagent in the containing cavity 1111 enters the different access pipes 1132 of the mixing output part 113 under the action of the pressure, and then is mixed in the mixing pipe 1131 and finally is output through the mixing output part 113. Then, no matter whether the reagents are mixed in the accommodating cavity 1111 or not, the mixing device can realize instant mixing output of different reagents through the mixing pipe, so that the reagent mixing speed is increased, and the production efficiency of the mixing device 11 is improved.

Optionally, as shown in fig. 2, the mixing device 11 further comprises a partition 114. The divider 114 is disposed within the receiving chamber 1111 and divides the receiving chamber 1111 into at least two sub-chambers, each for receiving a reagent. Specifically, the capacity of each sub-cavity can be equal or unequal. The height of the partition 114 may be less than or equal to the height of the receiving cavity 1111. The number of access tubes 1132 of the mixing output 113 is equal to the number of sub-chambers housing the chambers 1111, and there is only one access tube 1132 inside each sub-chamber. The containment chamber 1111 is divided by the provision of the divider 114 into a plurality of sub-chambers, each for containing one reagent, and a plurality of sub-chambers for containing at least two different reagents. Then, different reagents enter different access tubes 1132 of the mixing output member 113 under the action of gas pressure, are mixed in the mixing tube 1131 of the mixing output member 113, and are finally output through the mixing output member 113. Optionally, a switch may be disposed on each access tube 1132, and when more than three reagents are contained in the containing cavity 1111, the type of reagent mixing, for example, three reagents or two of the three reagents, may be controlled by controlling the switch of each access tube 1132. Through the setting, realize different reagents and save alone in different sub-chambeies, realize the demand that instant mixing output of instant needs on the one hand, on the other hand has also realized the control to reagent mixing type.

Alternatively, as shown in fig. 1 and 2, the partition 114 is detachably connected to the body 111. In particular, the detachable connection may be a threaded connection, a snap connection or two or more recesses provided in the body for positioning and securing the divider 114, with the divider 114 being disposed between the recesses to divide the chamber into a plurality of sub-chambers. Because the partition 114 can be detached, the reagents in the accommodating cavity 1111 can be conveniently mixed or isolated, and the application range of the mixing device 11 is expanded.

Alternatively, as shown in fig. 1 and 2, different access tubes 1132 of the mixing output element 113 are in contact with the reagents in different sub-chambers, respectively. Specifically, the distance between the end of the access tube 1132, which is in contact with the reagent in the containing cavity 1111, and the bottom of the containing cavity 1111 is not more than the preset distance. Preferably, the end of the access tube 1132 contacting the reagent in the containing chamber 1111 is set to be 5mm away from the bottom of the containing chamber 1111. With such an arrangement, the reagents in different sub-chambers enter different access pipes 1132 of the mixing output member 113 under the pressure of the compressed gas, and then are further mixed in a reagent mixing area formed by the access pipe 1132 and the mixing pipe 1131 of the mixing output member 113, and finally are output through the mixing output member 113. On the one hand, the mixing of different reagents in the mixing pipe 1131 is realized, and meanwhile, the effective utilization rate of the reagents is also improved, so that the device is environment-friendly and economical.

Optionally, as shown in fig. 3, the body 111 of the mixing device 11 includes a cavity and a cover 1112. The upper end of the cavity is provided with an opening and is used for forming an accommodating cavity 1111; the cover 1112 is used for closing the opening of the cavity to form a sealed space, and in particular, the shape of the cavity and the cover 1112 can be circular, square or other irregular patterns. Specifically, the compressed gas input pipe 112 and the mixing output member 113 penetrate the cover 1112. The compressed gas enters the sealed space formed by the cavity and the cover 1112 through the compressed gas input pipe 112, and under the action of the gas pressure, different reagents in the accommodating cavity 1111 enter different access pipes 1132 of the mixing output part 113, are further mixed in the mixing pipe 1131 of the mixing output part 113, and are finally output through the mixing output part 113. Through the arrangement, the detachable installation of the cavity and the cover 1112 in the body 111 is realized, and the cavity 1111, the cover 1112 and the mixing output part 113 are conveniently cleaned. Further, a pressure gauge 1114 is disposed on the cover 1112, and is used for monitoring the pressure in the sealed space formed by the cavity and the cover 1112, so as to adjust the flow rate of the input compressed gas in real time, and adjust the mixing rate of different reagents in the mixing tube 1131 in real time.

Optionally, as shown in fig. 1 and 3, the mixing device 11 further comprises a stirring member 115. Stirring piece 115 runs through lid 1112 and stretches into and holds chamber 1111 for to holding the reagent in the chamber 1111 and stir, stirring piece 115 is through linking bridge and lid 1112 fixed connection. Specifically, stirring member 115 can set up to a plurality ofly, arranges a plurality of subchambers that hold chamber 1111 in respectively, and the part that stirring member 115 and the reagent that holds in chamber 1111 contacted is provided with stirring fan blade, and the (mixing) shaft rotates and drives stirring fan blade rotation, and then stirs the mixture to the reagent that holds in chamber 1111, through the aforesaid setting, further promotes the mixing velocity and the homogeneity of reagent.

Optionally, as shown in fig. 1 and 3, the body 111 of the mixing device 11 further comprises a power device 1113. The power device 1113 is connected to the stirring member 115, and specifically, the power device 1113 may be an electric motor, a motor or other conventional power device, and is used to provide power to the stirring member 115 to drive the stirring member 115 to rotate so as to stir and mix the reagent in the containing chamber 1111. Through setting up power device 1113, further promote the mixing velocity and the homogeneity of reagent, improved mixing arrangement 11's mixing efficiency.

Optionally, as shown in fig. 1 and 2, the mixing device 11 further comprises a reagent input device 116. The reagent input device 116 is connected to the body 111 and communicates with the receiving chamber 1111 formed inside the body 111. Specifically, the reagent input device 116 includes, but is not limited to, a funnel, a reagent input tube, and the like. Through setting up reagent input device 116, be convenient for to holding chamber 1111 in input multiple reagent, promote the convenience of mixing arrangement 11 actual operation.

Optionally, as shown in fig. 1 and 3, the reagent input device 116 includes a plurality of sub-devices. Specifically, each sub-device is respectively communicated with a different sub-cavity of the accommodating cavity 1111, and is used for inputting a reagent into each sub-cavity, wherein when the number of the sub-devices is greater than or equal to 3, the reagents input by any two or more sub-devices can be the same or different. Through setting up a plurality of reagent input sub-devices, a plurality of sub-chambers that hold chamber 1111 in mixing arrangement 11 can save multiple reagent alone simultaneously, and mixing arrangement 11 can carry out instant needs and mix immediately as required, avoids the mixed solution of too early mixture to take place to deposit and the reagent that produces extravagant, promotes reagent effective utilization, economic environmental protection.

Optionally, as shown in fig. 1 and 3, at least one of the reagent input 116, the compressed gas input 112 and the mixing output 113 of the mixing device 11 is provided with a flow control device 117. Specifically, the flow control device 117 includes, but is not limited to, a ball valve, a flow regulating valve, etc., wherein any one or more of the reagent input device 116, the compressed gas input line 112, and the mixing output 113 may be provided with both a ball valve and a flow regulating valve. By setting the flow control device 117, the flow of the reagent input by the reagent input device 116, the flow of the compressed gas input by the compressed gas input pipe 112, and the flow of the mixed reagent in the input pipe 1132 and the output pipe 1131 of the mixing output part 113 can be adjusted in real time according to actual requirements, thereby further improving the controllability and practicability of the mixing device 11.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A mixing device, comprising:

the device comprises a body, a first reagent box and a second reagent box, wherein a containing cavity for containing at least two reagents is formed inside the body;

the compressed gas input pipe is connected with the body and used for inputting compressed gas into the accommodating cavity;

the mixing output part comprises a mixing pipe and at least two access pipes; one end of each access pipe is in contact with at least one reagent in the containing cavity, and the other end of each access pipe is communicated with the mixing pipe; the mixing pipe mixes the at least two reagents flowing in from the access pipe and outputs the mixed reagents.

2. The mixing device of claim 1, further comprising:

the separator is arranged in the accommodating cavity and divides the accommodating cavity into at least two sub-cavities, and each sub-cavity is used for accommodating one reagent.

3. The mixing device of claim 2, wherein the divider is removably connected to the body.

4. A mixing device according to claim 2 or 3, wherein different ones of said access tubes are in contact with different ones of said sub-chambers.

5. The mixing device of claim 1, wherein the body comprises:

the upper end of the cavity is opened and is used for forming the accommodating cavity;

the cover body is used for sealing the opening of the cavity;

wherein the compressed gas input tube and the mixing output member penetrate the cover body.

6. The mixing device of claim 5, further comprising:

the stirring piece penetrates through the cover body and extends into the accommodating cavity, and is used for stirring the at least two reagents; the stirring piece is fixedly connected with the cover body.

7. The mixing device of claim 6, wherein the body further comprises:

and the power device is used for being connected with the stirring piece to drive the stirring piece to rotate.

8. The mixing device of claim 1, further comprising:

and the reagent input device is connected with the body and is used for inputting the at least two reagents into the accommodating cavity.

9. The mixing device of claim 8, wherein the reagent input device comprises a plurality of sub-devices, each sub-device for inputting one reagent into the holding chamber, different sub-devices inputting different reagents.

10. The mixing device of claim 8, wherein at least one of the reagent input, the compressed gas input, and the mixing output is provided with a flow control device.