CN218901778U - Adapter plate for biopharmaceutical reactor - Google Patents

Abstract

The utility model provides an adapter plate for a biopharmaceutical reactor, which belongs to the technical field of biomedical equipment and comprises the following components: the adapter plate comprises an adapter plate body, a first adapter tube, a second adapter tube and a T-shaped connector; the adapter plate body is provided with a first connecting pipe and a plurality of second connecting pipes in a penetrating mode, and the second connecting pipes are arranged on the periphery of the first connecting pipe in a surrounding mode; the first connecting pipe is used for being connected with a feed inlet of the reaction tank, and the second connecting pipe is used for being connected with a discharge outlet of the material tank; the first transfer pipe is detachably arranged on the first transfer pipe; the second transfer pipe is detachably arranged on the second connecting pipe; one end of the T-shaped connector is rotationally connected with the first switching tube, and the other end of the T-shaped connector is fixedly connected with the second switching tube. The adapter plate for the biopharmaceutical reactor provided by the utility model not only can realize pipeline communication and switching between the material tank and the reaction tank, but also can effectively reduce the number of pipeline connection between the reaction tank and the material tank, and greatly improve the disassembly and assembly efficiency of the reaction tank.

Description

Adapter plate for biopharmaceutical reactor

Technical Field

The utility model belongs to the technical field of biopharmaceutical equipment, and particularly relates to an adapter plate for a biopharmaceutical reactor.

Background

The utility model provides a bio-pharmaceuticals reactor belongs to the conventional production facility of pharmacy trade, includes a plurality of material jar and retort, in actual production process, needs to pass through the pipeline with corresponding material according to production technology and carry to the retort in, need switch different production technologies in different periods, and a plurality of material jar all are connected with the retort direct through the pipeline among the prior art, need set up a plurality of feed inlets and the discharge gate of material jar on the retort promptly and be linked together, lead to the dismouting inefficiency of retort.

Disclosure of Invention

The utility model aims to provide an adapter plate for a biopharmaceutical reactor, and aims to solve the problem of low disassembly and assembly efficiency of a reaction tank in the existing biopharmaceutical reactor.

In order to achieve the above purpose, the utility model adopts the following technical scheme: there is provided an adapter plate for a biopharmaceutical reactor comprising:

the adapter plate body is provided with a first connecting pipe and a plurality of second connecting pipes in a penetrating manner, and the second connecting pipes are arranged on the periphery of the first connecting pipe in a surrounding manner; the first connecting pipe is used for being connected with a feed inlet of the reaction tank, and the second connecting pipe is used for being connected with a discharge outlet of the material tank;

the first connecting pipe is detachably arranged on the first connecting pipe;

the second switching tube is detachably arranged on the second connecting tube; and

t type connects, one end with first switching pipe rotates to be connected, the other end with second switching pipe fixed connection, T type connects is used for the intercommunication first switching pipe with the second switching pipe.

In one possible implementation manner, the T-shaped joint comprises a first straight pipe and a second straight pipe, the first straight pipe is vertical to the second straight pipe and communicated with the second straight pipe, the first straight pipe is sleeved on the first transfer pipe, the second straight pipe is fixedly connected with the second transfer pipe, and a material conveying hole communicated with the second straight pipe is formed in the side wall of the first transfer pipe.

In one possible implementation manner, a first annular groove is formed in the inner wall of the first straight pipe, the first annular groove is coaxially arranged with the first straight pipe, and the first annular groove is respectively communicated with the inner cavity of the second straight pipe and the material conveying hole.

In one possible implementation, a sealing ring is provided between the first straight tube and the first transfer tube.

In one possible implementation, the inner wall of the first straight tube is provided with a second annular groove for mounting the sealing ring.

In one possible implementation, the first straight tube is provided with a first jackscrew, and the first jackscrew abuts against the outer wall of the first adapter tube.

In one possible implementation manner, a proximity switch corresponding to the second transfer tube is installed on the transfer plate body, and the proximity switch is used for sensing materials in the second transfer tube.

In one possible implementation manner, an induction column is arranged on one side, close to the proximity switch, of the second transfer tube, and an inner cavity of the induction column is communicated with an inner cavity of the second transfer tube.

In one possible implementation, the induction column and the second adapter tube are fixed by welding.

In one possible implementation, the sensing column includes a support column and a telescoping column; the support column with second switching pipe fixed connection, the flexible post with support column coaxial and sliding fit.

Compared with the prior art, the scheme of the embodiment of the application shows that the adapter plate for the biopharmaceutical reactor has the advantages that the reaction tank is only provided with one feeding port, the feeding port is connected with the first connecting pipes on the adapter plate body through the pipelines, the number of the second connecting pipes on the adapter plate body is the same as that of the material tanks, the discharging ports of the material tanks are connected with the second connecting pipes through the pipelines, the first connecting pipes are provided with the first connecting pipes, the second connecting pipes are provided with the second connecting pipes, the first connecting pipes are rotatably provided with T-shaped connectors, and the T-shaped connectors are communicated with the first connecting pipes and the second connecting pipes. Because the second connecting pipe is arranged at the periphery of the first connecting pipe, the position of the second switching pipe can be changed by rotating the T-shaped joint, so that the second switching pipe moves to the corresponding second connecting pipe, and the switching of pipelines is realized. The adapter plate for the biopharmaceutical reactor can not only realize pipeline communication and switching between the material tank and the reaction tank, but also effectively reduce the pipeline connection quantity between the reaction tank and the material tank, and greatly improve the disassembly and assembly efficiency of the reaction tank.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a cross-sectional view of an adapter plate for a biopharmaceutical reactor according to an embodiment of the present utility model;

FIG. 2 is a top view of an adapter plate for a biopharmaceutical reactor according to an embodiment of the present utility model;

FIG. 3 is a cross-sectional view of a T-joint according to a second embodiment of the present utility model;

FIG. 4 is a second cross-sectional view of a T-joint according to a second embodiment of the present utility model;

fig. 5 is a cross-sectional view of an induction column according to a first embodiment of the present utility model.

In the figure: 1. an adapter plate body; 101. a first connection pipe; 102. a second connection pipe; 103. a material conveying hole; 104. a proximity switch; 2. a first transfer tube; 3. a second transfer tube; 301. an induction column; 302. a support column; 303. a telescopic column; 304. a second jackscrew; 4. a T-joint; 401. a first straight tube; 402. a second straight tube; 403. a first annular groove; 404. a seal ring; 405. a second annular groove; 406. a first jackscrew.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 and 2, an adapter plate for a biopharmaceutical reactor according to the present utility model will now be described. The adapter plate for the biopharmaceutical reactor comprises: the adapter plate comprises an adapter plate body 1, a first adapter tube 2, a second adapter tube 3 and a T-shaped joint 4; the adapter plate body 1 is provided with a first connecting pipe 101 and a plurality of second connecting pipes 102 in a penetrating way, and the plurality of second connecting pipes 102 are arranged on the periphery of the first connecting pipe 101 in a surrounding way; the first connecting pipe 101 is used for being connected with a feed port of the reaction tank, and the second connecting pipe 102 is used for being connected with a discharge port of the material tank; the first transfer tube 2 is detachably mounted on the first transfer tube 101; the second transfer tube 3 is detachably mounted on the second connection tube 102; one end of the T-shaped connector 4 is rotationally connected with the first adapter tube 2, the other end of the T-shaped connector is fixedly connected with the second adapter tube 3, and the T-shaped connector 4 is used for communicating the first adapter tube 2 and the second adapter tube 3.

Compared with the prior art, the adapter plate for the biopharmaceutical reactor provided by the embodiment has the advantages that only one feeding port is needed to be arranged in the reaction tank, the feeding port is connected with the first connecting pipes 101 on the adapter plate body 1 through pipelines, the number of the second connecting pipes 102 on the adapter plate body 1 is the same as that of the material tanks, the discharging ports of the material tanks are connected with the second connecting pipes 102 through pipelines, the first connecting pipes 2 are arranged on the first connecting pipes 101, the second connecting pipes 3 are arranged on the second connecting pipes 102, the T-shaped connectors 4 are rotatably arranged on the first connecting pipes 101, and the T-shaped connectors 4 are communicated with the first connecting pipes 2 and the second connecting pipes 3. Since the second connection pipe 102 is located at the outer circumference of the first connection pipe 101, the position of the second transfer pipe 3 can be changed by rotating the T-joint 4, so that the second transfer pipe 3 is moved to the corresponding second connection pipe 102, thereby realizing the switching of the pipelines. The adapter plate for the biopharmaceutical reactor can not only realize pipeline communication and switching between the material tank and the reaction tank, but also effectively reduce the pipeline connection quantity between the reaction tank and the material tank, and greatly improve the disassembly and assembly efficiency of the reaction tank.

In this embodiment, the first connection pipe 101 and the second connection pipe 102 are both kept perpendicular to the adapter plate body 1. The plurality of second transfer tubes 3 are arranged around the periphery of the first transfer tube 2, and the distances between the second transfer tubes 3 and the first transfer tube 2 are kept consistent. One end of the first adapter tube 2 positioned on the back surface of the adapter plate body 1 is connected with a feed inlet of the reaction tank through a pipeline, and one end of the second adapter tube 3 positioned on the back surface of the adapter plate body 1 is connected with a discharge outlet of the material tank through a pipeline. The first adapter tube 2, the second adapter tube 3 and the T-shaped joint 4 are all positioned on one side of the front surface of the adapter plate body 1. Except for the connection between the T-shaped joint 4 and the first adapter tube 2, other adjacent pipelines are connected by adopting a flange plate and bolt connection mode. At present, two production processes are adopted, two materials are needed for each production process, and the materials of the two production processes are different, so that the number of the material tanks is four. The number of the T-shaped joints 4 is two, and the number is the same as the type of materials to be conveyed each time. The two T-shaped connectors 4 are sequentially arranged on the first adapter tube 2 from top to bottom. The second transfer pipe 3 is kept away from the one end of T type joint 4 and buckles downwards, because there is the difference in height two T type joints 4 on first transfer pipe 2, so there is the difference in height also two second transfer pipe 3 decurrent bending section to satisfy second transfer pipe 3 and corresponding second connecting pipe 102 can well assemble.

In some embodiments, referring to fig. 1, 3 and 4, the t-shaped joint 4 includes a first straight tube 401 and a second straight tube 402, the first straight tube 401 and the second straight tube 402 are kept vertical and are mutually communicated, the first straight tube 401 is sleeved on the first transfer tube 2, the second straight tube 402 is fixedly connected with the second transfer tube 3, and a material conveying hole 103 communicated with the second straight tube 402 is formed in the side wall of the first transfer tube 2. In this embodiment, the first straight tube 401 and the second straight tube 402 are connected by welding. The second straight tube 402 is located at the center of the first straight tube 401 in the longitudinal direction. The first transfer pipe 2 is a structure with one end open and one end closed, the material conveying holes 103 are formed in the side wall of the first transfer pipe 2, the number of the material conveying holes 103 is multiple, and the material conveying holes are uniformly distributed along the circumferential direction of the first transfer pipe 2. Material passes from the second straight tube 402 through the feed aperture 103 into the first transfer tube 2.

In some embodiments, referring to fig. 1, 3 and 4, a first annular groove 403 is formed on the inner wall of the first straight tube 401, the first annular groove 403 is coaxially disposed with the first straight tube 401, and the first annular groove 403 is respectively communicated with the inner cavity of the second straight tube 402 and the feeding hole 103. In this embodiment, the width of the first annular groove 403 is larger than the aperture of the feeding hole 103. Since the inner wall of the first straight tube 401 is provided with the first annular groove 403, and the first annular groove 403 corresponds to the material conveying hole 103, the first straight tube 401 rotates by any angle, so that the inner cavity of the second straight tube 402 can be ensured to be communicated with the inner cavity of the first transfer tube 2.

In some embodiments, referring to fig. 3, a sealing ring 404 is disposed between the first straight tube 401 and the first adapter tube 2. In this embodiment, the number of sealing rings 404 is two, and the sealing rings are respectively located at two ends of the first straight tube 401 in the length direction. The seal 404 is made of polyacrylate rubber. The polyacrylate rubber has the advantages of high temperature resistance and wear resistance, has good sealing effect on engine oil, heat conducting oil and the like, and can effectively prevent oil leakage of the roller.

In some embodiments, referring to fig. 3, the inner wall of the first straight tube 401 is provided with a second annular groove 405 for mounting a sealing ring 404. In this embodiment, the sealing ring 404 is made of flexible material, and is capable of being elastically deformed by force. The second annular groove 405 can play a limiting role on the sealing ring 404, so that the sealing ring 404 is prevented from displacing relative to the first straight pipe 401 and even separating from the first straight pipe 401. In order to make the connection between the sealing ring 404 and the first straight tube 401 stronger, glue can be applied in the second annular groove 405, and the sealing ring 404 is adhered and fixed by using the viscosity of the glue.

In some embodiments, referring to fig. 3, a first straight tube 401 is provided with a first jackscrew 406, and the first jackscrew 406 abuts against the outer wall of the first adapter tube 2. In this embodiment, a threaded hole for mounting the first jackscrew 406 is formed in the side wall of the first straight tube 401. The first straight tube 401 is kept relatively stable with respect to the first adapter tube 2 by rotating the first jackscrew 406 such that the first jackscrew 406 abuts against the outer wall of the first adapter tube 2. When the first straight tube 401 needs to be rotated, the first jackscrew 406 is unscrewed.

In some embodiments, referring to fig. 1, a proximity switch 104 corresponding to the second transfer tube 3 is installed on the transfer board body 1, and the proximity switch 104 is used for sensing the material in the second transfer tube 3. In the present embodiment, the number of the proximity switches 104 is the same as the number of the second connection pipes 102, and the proximity switches 104 are located between the first connection pipe 101 and the second connection pipe 102 while being located directly below the second transfer pipe 3. The proximity switch 104 is fixedly installed on the adapter plate body 1. During the material conveying process, the proximity switch 104 can sense the material of the second transfer tube 3, so as to conveniently confirm whether the material is smoothly conveyed.

In some embodiments, referring to fig. 1, a sensing post 301 is disposed on a side of the second adapter tube 3 near the proximity switch 104, and an inner cavity of the sensing post 301 is in communication with an inner cavity of the second adapter tube 3. In this embodiment, the sensing post 301 is a hollow cylinder. The sensing post 301 remains perpendicular to the second transfer tube 3. The sensing post 301 is located directly above the proximity switch 104. The upper end opening of the induction column 301 is communicated with the second transfer tube 3, and the lower end of the induction column 301 is of a closed structure. The material in the second transfer tube 3 can enter the induction column 301. Because the induction distance of the proximity switch 104 is limited, the distance between the proximity switch 104 and the material in the pipeline can be effectively shortened by arranging the induction column 301 on the second transfer column, so that the proximity switch 104 can work normally.

In some embodiments, the induction post 301 and the second transfer tube 3 are secured by welding.

In some embodiments, referring to fig. 5, the sensing post 301 includes a support post 302 and a telescoping post 303; the support column 302 is fixedly connected with the second adapter tube 3, and the telescopic column 303 is coaxial with the support column 302 and is in sliding fit. In this embodiment, the support posts 302 have a structure with two open ends. The telescopic column 303 is an opening at one end and a closed structure at the other end. The upper end of the support column 302 is fixed to the second adapter tube 3 by welding. The open end of telescoping post 303 fits over support post 302 and is a sliding fit with support post 302. The telescopic column 303 can slide on the support column 302 along its own axial direction, so as to adjust the length dimension of the sensing column 301, i.e. change the distance between the sensing column 301 and the proximity switch 104, so that the distance between the sensing column 301 and the proximity switch 104 is within the reaction distance of the proximity switch 104. In order to ensure that the telescopic column 303 and the support column 302 remain relatively stable in the working state, a second jackscrew 304 may be disposed between the support column 302 and the telescopic column 303, and a threaded hole for mounting the second jackscrew 304 is formed in the outer wall of the telescopic column 303. The second jack screw 304 abuts against the outer side wall of the support column 302, thereby locking the telescopic column 303.

It should be noted that: the second transfer tubes 3 may be identical or different in structure or size, and the sensing posts 301 on each second transfer tube 3 may be identical or different in length size. The structures of the second adapter tube 3 and the induction column 301 can be adapted according to practical conditions, so that assembly can be finally achieved.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. An adapter plate for a biopharmaceutical reactor, comprising:

the adapter plate body is provided with a first connecting pipe and a plurality of second connecting pipes in a penetrating manner, and the second connecting pipes are arranged on the periphery of the first connecting pipe in a surrounding manner; the first connecting pipe is used for being connected with a feed inlet of the reaction tank, and the second connecting pipe is used for being connected with a discharge outlet of the material tank;

the first connecting pipe is detachably arranged on the first connecting pipe;

the second switching tube is detachably arranged on the second connecting tube; and

t type connects, one end with first switching pipe rotates to be connected, the other end with second switching pipe fixed connection, T type connects is used for the intercommunication first switching pipe with the second switching pipe.

2. The adapter plate for a biopharmaceutical reactor of claim 1, wherein the T-shaped connector comprises a first straight tube and a second straight tube, wherein the first straight tube is vertically and mutually communicated with the second straight tube, the first straight tube is sleeved on the first adapter tube, the second straight tube is fixedly connected with the second adapter tube, and a material conveying hole communicated with the second straight tube is formed in the side wall of the first adapter tube.

3. The adapter plate for a biopharmaceutical reactor of claim 2, wherein a first annular groove is provided in the inner wall of the first straight tube, the first annular groove being coaxially disposed with the first straight tube, the first annular groove being in communication with the inner cavity of the second straight tube and the feed delivery hole, respectively.

4. An adapter plate for a biopharmaceutical reactor as claimed in claim 2, wherein a sealing ring is provided between the first straight tube and the first adapter tube.

5. An adapter plate for a biopharmaceutical reactor as in claim 4, wherein the inner wall of the first straight tube is provided with a second annular groove for mounting the sealing ring.

6. An adapter plate for a biopharmaceutical reactor as claimed in claim 2, wherein the first straight tube is provided with a first jackscrew which abuts against the outer wall of the first adapter tube.

7. The adapter plate for a biopharmaceutical reactor of claim 1, wherein the adapter plate body is provided with a proximity switch corresponding to the second adapter tube, the proximity switch being adapted to sense material in the second adapter tube.

8. The adapter plate for a biopharmaceutical reactor of claim 7, wherein the second adapter tube has an induction post on a side thereof adjacent to the proximity switch, and wherein the inner cavity of the induction post is in communication with the inner cavity of the second adapter tube.

9. The adapter plate for a biopharmaceutical reactor of claim 8, wherein the sensing post and the second adapter tube are welded together.

10. The adapter plate for a biopharmaceutical reactor of claim 8, wherein the sensing column comprises a support column and a telescoping column; the support column with second switching pipe fixed connection, the flexible post with support column coaxial and sliding fit.

Images