CN101955067A

CN101955067A - Transmitter and using method and transmission method thereof

Info

Publication number: CN101955067A
Application number: CN2009103044068A
Authority: CN
Inventors: 陆洪瑞
Original assignee: Beijing Yinrong Technology Co Ltd
Current assignee: Beijing Yinrong Technology Co Ltd
Priority date: 2009-07-16
Filing date: 2009-07-16
Publication date: 2011-01-26

Abstract

The invention discloses a transmitter and a using method and a transmission method thereof, relates to the field of pneumatic pipeline transmission, and aims to reduce error operation during transmission of the transmitter and improve the transmission reliability. The transmitter is used for a pneumatic pipeline transmission system and comprises a shell and an inner core, wherein the shell has a cylindrical shape, an enclosed bottom end and a top end with an opening; and the inner core has a cylindrical shape and is arranged inside the shell in a pluggable mode; and a run-resistant structure is arranged between the shell and the inner core. The method for using the transmitter comprises the following step of: in the process of drawing the inner core of the transmitter out of the shell, preventing the inner core from being completely disengaged from the shell by using the run-resistant structure between the inner core and the shell of the transmitter. The transmitter and the using method and the transmission method thereof are applied to the pneumatic pipeline transmission system.

Description

Transmitter and using method and transmission method thereof

Technical Field

The invention relates to the field of pneumatic pipeline transmission, in particular to a transmitter used in a pneumatic pipeline transmission system and a using method thereof.

Background

The pneumatic pipeline transmission system is a modern rapid logistics transmission tool. The pneumatic pipeline transmission system is applied to places such as hospitals, banks, office buildings, supermarkets, production workshops and laboratories, which need to convey a large number of articles every day. Any suitable volume of items such as medical records, diagnostic books, medications, laboratory test orders, tickets, cash, documents, etc. may be delivered.

As shown in fig. 1, the conventional pneumatic pipeline transmission system includes a sending workstation, a receiving workstation, and a transmission pipeline connected to the sending workstation and the receiving workstation, and the transmission pipeline is connected to an air source device.

When an article needs to be conveyed from a sending workstation to a receiving workstation, the article to be conveyed is placed into a conveyer, then the conveyer is placed into the sending workstation, an air source device is started, and the conveyer is conveyed from the sending workstation to the receiving workstation under the action of air flow.

Existing transmitters include an outer housing and an inner core disposed within the outer housing. Wherein the inner core is capable of being pulled out of the outer shell and separated from the outer shell. And after the article to be transmitted is placed into the inner core through a door opening arranged on the inner core, the inner core is reinserted into the shell, and then the transmitter is placed into the pneumatic transmission pipeline for transmission.

In the prior art, after the inner core is pulled out of the outer shell, the inner core is separated from the outer shell, and in actual operation, due to misoperation of an operator, the inner core or the outer shell is often independently placed into a pneumatic transmission pipeline for transmission, so that the transmission reliability of the transmitter is reduced.

Disclosure of Invention

The invention aims to provide a transmitter, which can reduce misoperation when the transmitter is transmitted and improve the reliability of transmission.

In order to achieve the purpose, the technical scheme adopted by the transmitter is as follows:

a conveyor for a pneumatic pipe transport system, comprising: the shell is cylindrical, the bottom end of the shell is closed, and the top end of the shell is provided with an opening; the inner core is cylindrical and is arranged in the shell in a pluggable manner; an anti-falling structure is arranged between the outer shell and the inner core.

Wherein, anti-disengaging structure includes: a flange arranged on the inner wall of the opening at the top end of the shell; the boss is arranged on the outer side wall of the bottom end of the inner core; wherein, the bottom of inner core stretches into inside the shell.

The anti-falling structure is a flexible traction rope or a spring, and two ends of the anti-falling structure are respectively fixed at the bottom of the inner core and the bottom of the outer shell.

Optionally, the anti-dropping structure includes: the guide rail is arranged on the outer side of the inner core, extends along the axial direction of the inner core, and is provided with a boss at one end close to the bottom end of the inner core; and

the guide rail is arranged in the guide groove in a sliding manner, and a stop block is arranged at one end, close to the top end of the shell, of the guide groove.

Furthermore, a positioning structure is arranged between the outer shell and the inner core; wherein, the location structure includes: the groove is arranged on the inner wall of the shell; and the elastic bulge is arranged on the outer side wall of the inner core and matched with the groove; or

The positioning structure includes: the elastic bulge is arranged on the inner wall of the shell; and the groove is arranged on the outer side wall of the inner core and matched with the elastic bulge.

Optionally, the positioning structure comprises: the groove is arranged on the flange at the top end of the shell; and the elastic bulge is arranged on the outer side wall of the inner core and matched with the groove.

Furthermore, an elastic component is arranged between the bottom of the inner core and the bottom of the outer shell.

Compared with the prior art, the anti-disengaging structure is arranged between the outer shell and the inner core of the conveyor, so that when the inner core is pulled out of the outer shell, the anti-disengaging structure can prevent the inner core from disengaging from the outer shell, and the inner core and the outer shell are always connected together even if the conveyor is in an open state. The problem of misoperation that an operator inserts the inner core into the shell and puts the inner core or the shell into a transmission system for transmission due to forgetting is avoided, and the transmission reliability is improved.

Another object of the present invention is to provide a method for using a transmitter, which can reduce the misoperation during the transmission of the transmitter and improve the reliability of the transmission.

In order to achieve the purpose, the using method of the transmitter adopts the technical scheme that:

a use method of a conveyer is applied to pneumatic pipeline conveying and comprises the following steps:

the anti-separation structure between the inner core and the outer shell of the conveyor prevents the inner core from completely separating from the outer shell when the inner core of the conveyor is pulled out of the outer shell.

The anti-falling structure between the inner core and the outer shell of the transmitter prevents the inner core from completely separating from the outer shell, and the anti-falling structure comprises the following specific steps:

a lug boss arranged on the outer side of the inner core is blocked by a flange at the opening of the shell, so that the inner core is prevented from completely separating from the shell; or

The traction ropes arranged at the bottom of the inner core and the bottom of the outer shell drag the inner core to prevent the inner core from completely separating from the outer shell; or

The springs arranged at the bottom of the inner core and the bottom of the shell pull the inner core to prevent the inner core from completely separating from the shell.

Further, the method further comprises: springs disposed at the bottom of the inner core and the bottom of the outer shell pull the inner core into the outer shell, the inner core being positioned inside the outer shell.

Wherein the positioning of the inner core inside the outer shell specifically is: and elastic protrusions on the inner wall of the shell are embedded into grooves on the outer side wall of the inner core, so that the inner core is positioned inside the shell.

Compared with the prior art, the use method of the conveyor has the advantages that when the inner core of the conveyor is pulled out of the outer shell, the inner core is prevented from being completely separated from the outer shell by the anti-falling structure between the inner core and the outer shell of the conveyor, so that the inner core and the outer shell are always connected together even if the conveyor is in an open state. The problem of misoperation that an operator inserts the inner core into the shell and puts the inner core or the shell into a transmission system for transmission due to forgetting is avoided, and the transmission reliability is improved.

Another object of the present invention is to provide a transmission method for a transmitter, which can reduce the misoperation when the transmitter is transmitted, and improve the reliability of transmission.

A transmission method of a transmitter, comprising:

drawing the inner core of the conveyor out of the outer shell, exposing a doorway arranged on the inner core, and connecting the inner core and the outer shell together;

placing an article to be transported into the core from a doorway in the core;

and inserting the inner core into the outer shell, and putting the transmitter into a work station of a pneumatic transmission pipeline for transmission.

Compared with the prior art, the transmission method of the transmitter has the advantages that the inner core of the transmitter is drawn out of the outer shell, and when the door opening on the inner core is exposed, the inner core and the outer shell are connected together; therefore, the problem of misoperation of transmission when an operator forgets to insert the inner core into the shell and puts the inner core or the shell into the transmission system is avoided, and the transmission reliability is improved.

The transmitter core and the barrel body have good integrity, the material is saved, the manufacture is easy, and the transmission core is durable; meanwhile, the problem that the transmission objects are scattered and cause large faults when the transmission objects are placed in the transmission system without being inserted together is solved.

Further to the method of use as described above,

the positioning of the inner core inside the outer shell specifically comprises:

and elastic protrusions on the inner wall of the shell are embedded into grooves on the outer side wall of the inner core, so that the inner core is positioned inside the shell.

A transmission method of a transmitter, comprising:

placing an article to be transported into the core from a doorway in the core;

Further, the transmission method described above further includes:

if the inner core of the transmitter is not inserted into the shell, the transmitter is placed into the workstation, and the door body of the workstation cannot be closed; and/or

If the inner core of the transmitter is not inserted into the shell, the transmitter is placed into the workstation, and the wind source device of the transmission system is in a locked state and cannot be started; and/or

If the inner core of the transmitter is not inserted into the shell, the transmitter is placed into the workstation, and the door body of the workstation cannot be closed.

Further, the transmission method described above further includes:

if the inner core of the transmitter is not inserted into the outer shell, the transmitter is placed into the workstation, and the transmitter is over-high, so that the container of the workstation cannot be closed in place.

Further, the transmission method described above further includes:

if the inner core of the transmitter is not inserted into the outer shell, the transmitter is placed into the workstation, and the outer shell or the inner core of the transmitter exposed outside the workstation drags the other part of the transmitter, namely the inner core or the outer shell, placed into the workstation; the transmitter cannot transmit.

Drawings

FIG. 1 is a top view of a conveyor embodiment 1 of the invention;

FIG. 2 is a cross-sectional view of the conveyor of FIG. 1 taken along line B-B;

FIG. 3 is a cross-sectional view of the inner core of the conveyor of FIG. 2 in a pulled out condition;

FIG. 4 is a schematic perspective view of the inner core of the conveyor of FIG. 2 in a pulled-out position;

fig. 5 is a schematic perspective view of the core of the conveyor of embodiment 1 of the invention;

FIG. 6 is a cross-sectional view of embodiment 2 of the conveyor of the invention;

fig. 7 is a schematic perspective view of the inner core of the transmitter according to embodiment 3 of the present invention;

fig. 8 is a schematic perspective view of a housing of a transmitter according to embodiment 3 of the present invention;

FIG. 9 is a cross-sectional view of another embodiment of a conveyor of the invention;

FIG. 10 is a cross-sectional view of yet another embodiment of the inventive conveyor;

FIG. 11 is a schematic view of the closed position of the workstation receiver;

FIG. 12 is a schematic view of the container in the flipped open position into the conveyor;

FIG. 13 is a schematic structural view of the container in a closed state, wherein the container is a section of pipe with a flat opening at the upper port;

fig. 14 is a schematic structural view of the container in an open state, wherein the container is a section of pipe with a flat opening at an upper port.

Detailed Description

The invention aims to provide a transmitter and a using method thereof, which can reduce misoperation during transmission of the transmitter and improve the reliability of transmission. The present invention will be described in detail below with reference to the accompanying drawings and examples.

The invention relates to a transmitter for a pneumatic pipeline transmission system, which comprises: the shell is cylindrical, the bottom end of the shell is closed, and the top end of the shell is provided with an opening; the inner core is cylindrical and can be arranged in the shell in a pluggable manner, and a door opening is formed in the inner core and used for placing articles into the inner core from the door opening or taking articles out of the inner core; an anti-falling structure is arranged between the outer shell and the inner core.

Due to the anti-falling structure arranged between the outer shell and the inner core of the conveyor, when the inner core is pulled out of the outer shell, the anti-falling structure can prevent the inner core from being separated from the outer shell, so that the inner core and the outer shell are always connected together even if the conveyor is in an open state. The problem of misoperation that an operator inserts the inner core into the shell and puts the inner core or the shell into a transmission system for transmission due to forgetting is avoided, and the transmission reliability is improved.

Example 1

Referring to fig. 1 to 5, the conveyor of the present embodiment, which is used for a pneumatic pipeline conveying system, includes: the device comprises a shell 1, a first fixing device and a second fixing device, wherein the shell is cylindrical, the bottom end of the shell is closed, and the top end of the shell is provided with an opening; the inner core 2 is cylindrical, the top end of the inner core is closed, the inner core is arranged in the shell in a pluggable mode, a door opening 3 is formed in the side wall of the inner core and used for placing articles into the inner core from the door opening or taking articles out of the inner core; be equipped with anti-disengaging structure between shell and the inner core, wherein, anti-disengaging structure includes: a flange 4 arranged on the inner wall of the top opening of the shell; and a boss 5 arranged on the outer side wall of the bottom end of the inner core; wherein the bottom end of the inner core extends into the interior of the outer shell.

When the inner core 2 of the conveyor is pulled out of the outer shell 1, the flange 4 arranged on the inner wall of the opening at the top end of the outer shell plays a role of blocking the boss 5 arranged on the outer side wall at the bottom end of the inner core, and the inner core is prevented from completely separating from the outer shell.

Example 2

Referring to fig. 6, this embodiment is substantially the same as embodiment 1, except that the anti-separation structure in this embodiment is a spring 7 having two ends fixed to the bottom of the inner core and the bottom of the outer shell, respectively.

The spring is used as an anti-falling structure, when the inner core is pulled out of the outer shell, the inner core can be pulled, and the inner core is prevented from being separated from the outer shell; after articles are put into the inner core or taken out of the inner core, the spring contracts under the action of elastic restoring force, the inner core can be automatically pulled into the shell, and finally the inner core is tensioned and abutted against the bottom of the shell, so that the inner core is positioned.

Of course, the anti-dropping structure can also adopt a common flexible traction rope to achieve the purpose of connecting the inner core and the outer shell together.

Example 3

Referring to fig. 7 and 8, the present embodiment is substantially the same as embodiment 1, except that the anti-falling structure in the present embodiment includes: the guide rail 15 is arranged on the outer side of the inner core 2, the guide rail extends along the axial direction of the inner core, and a boss is arranged at one end of the guide rail close to the bottom end of the inner core; and a guide groove 16 arranged on the inner side wall of the shell 1, wherein the guide rail is arranged in the guide groove in a sliding way, and a stop block is arranged at one end of the guide groove close to the top end of the shell.

The inner core can slide in the shell along the guide groove through the guide rail, but when the inner core is drawn out for a certain length, the stop block stops the boss, and the inner core is prevented from being separated from the shell.

In addition, the guide rail guide groove structure can also play a role in guiding the sliding of the inner core in the guide rail.

Further, in each of the above embodiments, a positioning structure is further provided between the outer shell and the inner core so as to limit the inner core in the outer shell, and avoid the inner core moving freely inside the outer shell when the transmitter transmits in the pneumatic pipeline transmission system, which results in collision between the inner core and the outer shell.

Referring to fig. 1, 3 and 6, the positioning structure includes: a groove 8 arranged on the inner wall of the shell; and an elastic bulge 9 which is arranged on the outer side wall of the inner core and is matched with the groove.

When the inner core is positioned in the shell and the elastic bulge 9 on the outer side wall of the inner core is embedded into the groove 8 on the inner wall of the shell, the inner core and the shell are relatively fixed.

Of course, the positioning structure can also adopt the following structure: namely the positioning structure: the elastic bulge is arranged on the inner wall of the shell; and the groove is arranged on the outer side wall of the inner core and matched with the elastic bulge.

Referring to fig. 9, the positioning structure may also adopt the following structure: namely, the positioning structure includes: the groove is arranged on the flange at the top end of the shell; and the elastic bulge is arranged on the outer side wall of the inner core and matched with the groove. The groove is formed in the flange at the top end of the shell, so that the inner core and the shell are more convenient to position and fix, and the elastic bulge on the outer side wall of the inner core can be made to be relatively short, so that the material is saved.

Referring to fig. 10, the positioning structure may also adopt the following structure: namely, the elastic pieces 10 are arranged on both sides of the top end of the inner core. And the inner core is fixed in the shell under the tensioning action between the elastic sheet and the top opening of the shell.

Referring to fig. 10, in order to ensure that the core is reliably and reliably fixed inside the housing by the above-described positioning structure, an elastic member 11, such as a cylindrical spring or a leaf spring, is provided between the bottom of the core and the bottom of the housing. When the core is securely held inside the shell, the length of the core extending out of the top of the shell is constant. When the inner core is not fixed inside the outer shell through the positioning structure, the elastic component 11 will push the inner core out towards the direction outside the top opening of the outer shell, so that the length of the inner core extending out of the top of the outer shell is greater than the preset length. Therefore, whether the inner core is reliably fixed in the outer shell through the positioning structure can be judged by observing the length of the inner core extending out of the top of the outer shell. When the inner core is not fixed in the shell through the positioning structure, the transmitter is prevented from being thrown into a pneumatic transmission pipeline for transmission.

The embodiment of the invention also provides a using method of the conveyer, which is applied to pneumatic pipeline transmission and comprises the following steps:

Since the core is prevented from completely separating from the outer case by the anti-separation structure between the core and the outer case of the conveyor when the core of the conveyor is pulled out of the outer case, the core and the outer case are always connected even when the conveyor is in an open state. The problem of misoperation that an operator inserts the inner core into the shell and puts the inner core or the shell into a transmission system for transmission due to forgetting is avoided, and the transmission reliability is improved.

Further, the method further comprises: after an article is put into the inner core or taken out of the inner core, the springs arranged at the bottom of the inner core and the bottom of the outer shell contract under the action of elastic restoring force, the inner core is pulled into the outer shell, and finally the inner core is tensioned and is abutted against the bottom of the outer shell, so that the inner core is positioned in the outer shell.

The embodiment of the invention also provides a transmission method of the transmitter, which comprises the following steps:

placing an article to be transported into the core from a doorway in the core;

When the inner core of the transmitter is drawn out of the outer shell and the door opening on the inner core is exposed, the inner core and the outer shell are connected together; therefore, the problem of misoperation of transmission when an operator forgets to insert the inner core into the shell and puts the inner core or the shell into the transmission system is avoided, and the transmission reliability is improved.

Further, the method further comprises:

And if the inner core of the transmitter is not inserted into the shell, the transmitter is placed into the workstation, and the wind source device of the transmission system is in a locked state and cannot be started.

Therefore, the pneumatic transmission of the transmitter can be ensured only when the inner core of the transmitter is surely and reliably inserted into the outer shell, and the phenomenon that the transmitter is placed into a pneumatic transmission pipeline for transmission when the inner core and the outer shell are not inserted together, so that the transmitted objects are scattered and large faults are caused is avoided.

Example four

As shown in fig. 11 and 12, the trading system workstation according to the embodiment of the present invention includes a vertical pipe 10, a port 11 is provided at a lower end of the vertical pipe 10, a receiver 12 is pivoted at the port 11 at the lower end of the vertical pipe, the receiver is pivoted on a frame 13 through a pivot shaft 15, the vertical pipe 10 is fixed on the frame 13, an opening 14 is provided at an upper end of the receiver, the opening 14 at the upper end of the receiver is matched with the port 11 at the lower end of the vertical pipe, wherein the port 11 at the lower end of the vertical pipe is an inclined port; as shown in fig. 13, the container 12 is a pipe section with a closed bottom and an inclined opening at the upper end, and the pipe section has a containing space for containing an object 100 (such as a conveyor) to be sent or received; the container is pivoted to the inclined ports at the lower ends of the vertical pipes by a pivot shaft 15 fixed to the pipe section, and can be turned over in the normal direction of the inclined ports at the lower ends of the vertical pipes, as shown in fig. 12. In order to facilitate the fixed installation of the pipe and the container, thereby forming an integrated product, the workstation further comprises a frame body; the vertical pipeline is fixed on the frame body, and the container is pivoted on the frame body through the pivoting shaft.

Further, in order to enable the container to realize self-locking by means of self-gravity when the inclined opening at the upper end of the container is matched with the inclined port at the lower end of the vertical pipeline, the pivot shaft 15 is arranged at the bottom of the container and is deviated from one side of the central line of the bottom of the container, which is close to the overturning opening direction of the container.

Furthermore, in order to be able to turn the container 12 into a suitable operating position, the station is provided with a stop element 16 which limits the turning angle of the tube section.

Further, in order to achieve that the inclined port at the lower end of the vertical pipeline and the inclined opening at the upper end of the container can be aligned and matched well and have a good sealing effect, a step is arranged on a matching surface of the inclined port at the lower end of the vertical pipeline and the inclined opening at the upper end of the container, that is, the matching surface of the inclined port at the lower end of the vertical pipeline and the inclined opening at the upper end of the container is a step-type matching surface.

In this embodiment, the vertical pipe and the container are formed by a wire cutting process from the same pipe. The matching surface formed by linear cutting is compact, and a good sealing effect can be achieved.

In this embodiment, the container is opened manually, and in order to facilitate the manual opening, a handle 12a is provided on the container.

EXAMPLE five

As shown in fig. 13 and 14, the trading system workstation according to the embodiment of the present invention includes a vertical pipe 20, a port 21 is provided at a lower end of the vertical pipe, a container 22 is pivoted at the port at the lower end of the vertical pipe, an opening 23 is provided at an upper end of the container, and the opening 23 at the upper end of the container is matched with the port 21 at the lower end of the vertical pipe; wherein,

the port 21 at the lower end of the vertical pipeline is a horizontal port; the container 22 is a pipe section with a closed bottom and a horizontal opening at the upper end, and the pipe section is provided with a containing space for containing an object 200 (such as a conveyor) to be sent or received; the container is vertically pivoted at a horizontal port at the lower end of the vertical pipe by a pivot shaft 24 fixed to the pipe section.

Further, in order to realize automatic control, the container is connected with a driving mechanism for driving the container to rotate and reset. The container is made of stainless steel, and the driving mechanism comprises an electromagnet arranged on a rotating path of the container and a torsion spring sleeved on the pivot shaft.

Further, a through hole is formed at the bottom of the container 22, so that the air pressure in the vertical pipe is communicated with the external atmosphere.

Further, a buffering member (not shown), such as a rubber pad or a spring, is provided at the bottom inside the container, so that when an article falls into the container from the vertical duct, the impact of the article on the container can be reduced.

The container can be pivoted at a port at the lower end of the vertical pipeline and can also be slidably arranged at the port at the lower end of the vertical pipeline. The receiver is slidably disposed at the port of the lower end of the vertical pipe.

Thus; and if the inner core of the transmitter is not inserted into the outer shell, the transmitter is placed into the workstation, and the transmitter is over-high, so that the container of the workstation cannot be closed in place.

Further on

If the inner core of the transmitter is not inserted into the outer shell, the transmitter is placed into the workstation, the outer shell or the inner core of the transmitter exposed outside the workstation drags the inner core or the outer shell of the other part of the transmitter placed in the workstation, namely the inner core or the outer shell, namely the two bodies of the transmitter inside and outside the container are pulled by the rope; disabling the transmitter from transmitting.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. A conveyor for a pneumatic pipe transport system, comprising:

the shell is cylindrical, the bottom end of the shell is closed, and the top end of the shell is provided with an opening;

the inner core is cylindrical and is arranged in the shell in a pluggable manner;

it is characterized in that an anti-drop structure is arranged between the outer shell and the inner core.

2. The conveyor of claim 1, wherein the anti-drop structure comprises: a flange arranged on the inner wall of the opening at the top end of the shell; the boss is arranged on the outer side wall of the bottom end of the inner core; wherein

The bottom end of the inner core extends into the shell.

3. The conveyor of claim 1, wherein the anti-slip structure is a flexible pulling rope or a spring with two ends fixed to the bottom of the inner core and the bottom of the outer shell respectively.

4. The conveyor of claim 1, wherein the anti-drop structure comprises:

the guide rail is arranged on the outer side of the inner core, extends along the axial direction of the inner core, and is provided with a boss at one end close to the bottom end of the inner core; and

5. A conveyor as claimed in claim 2 or claim 3, wherein locating formations are provided between the outer shell and inner core; wherein

The positioning structure includes: the groove is arranged on the inner wall of the shell; and the elastic bulge is arranged on the outer side wall of the inner core and matched with the groove; or

6. The conveyor of claim 2, wherein a locating structure is further provided between the outer shell and the inner core; wherein

The positioning structure includes: the groove is arranged on the flange at the top end of the shell; and

and the elastic bulge is arranged on the outer side wall of the inner core and matched with the groove.

7. The conveyor of claim 5, further comprising a resilient member between the core bottom and the shell bottom.

8. The use method of the conveyer is applied to pneumatic pipeline conveying, and is characterized by comprising the following steps:

9. The use method according to claim 8, wherein the anti-separation structure between the inner core and the outer shell of the conveyor prevents the inner core from completely separating from the outer shell by:

10. The method of use of claim 8, further comprising:

springs disposed at the bottom of the inner core and the bottom of the outer shell pull the inner core into the outer shell, the inner core being positioned inside the outer shell.